Effects of BDNF and NT-3 on development of Ia/motoneuron functional connectivity in neonatal rats.
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Effects of BDNF and NT-3 on development of Ia/motoneuron functional connectivity in neonatal rats. The effects of neurotrophin administration and neurotrophin removal via administration of tyrosine kinase (trk) immunoadhesins (trk receptor extracellular domains fused with IgG heavy chain) on the development of segmental reflexes were studied in neonatal rats. Brain derived neurotrophic factor (BDNF), neurotrophin-3 (NT-3), trkB-IgG, and trkC-IgG were delivered via subcutaneous injection on days 0, 2, 4, and 6 of postnatal life. Electrophysiological analysis of EPSPs recorded intracellularly in L5 motoneurons in response to stimulation of dorsal root L5 was carried out on postnatal day 8 in the in vitro hemisected spinal cord. Treatment with BDNF resulted in smaller monosynaptic EPSPs with longer latency than those in controls. EPSP amplitude became significantly larger when BDNF was sequestered with trkB-IgG, suggesting that BDNF has a tonic action on the development of this synapse in neonates. Treatment with NT-3 resulted in larger EPSPs, but the decrease noted after administration of trkC-IgG was not significant. Neurotrophins had little effect on the response to high-frequency dorsal root stimulation or on motoneuron properties. Polysynaptic components were exaggerated in BDNF-treated rats and reduced after NT-3 compared with controls. As in control neonates the largest monosynaptic EPSPs in NT-3 and trkB-IgG-treated preparations were observed in motoneurons with relatively large values of rheobase, probably those that are growing the most rapidly. We conclude that supplementary NT-3 and BDNF administered to neonates can influence developing Ia/motoneuron synapses in the spinal cord but with opposite net effects. (+info)
Encoding of visual information by LGN bursts.
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Encoding of visual information by LGN bursts. Thalamic relay cells respond to visual stimuli either in burst mode, as a result of activation of a low-threshold Ca2+ conductance, or in tonic mode, when this conductance is inactive. We investigated the role of these two response modes for the encoding of the time course of dynamic visual stimuli, based on extracellular recordings of 35 relay cells from the lateral geniculate nucleus of anesthetized cats. We presented a spatially optimized visual stimulus whose contrast fluctuated randomly in time with frequencies of up to 32 Hz. We estimated the visual information in the neural responses using a linear stimulus reconstruction method. Both burst and tonic spikes carried information about stimulus contrast, exceeding one bit per action potential for the highest variance stimuli. The "meaning" of an action potential, i.e., the optimal estimate of the stimulus at times preceding a spike, was similar for burst and tonic spikes. In within-trial comparisons, tonic spikes carried about twice as much information per action potential as bursts, but bursts as unitary events encoded about three times more information per event than tonic spikes. The coding efficiency of a neuron for a particular stimulus is defined as the fraction of the neural coding capacity that carries stimulus information. Based on a lower bound estimate of coding efficiency, bursts had approximately 1.5-fold higher efficiency than tonic spikes, or 3-fold if bursts were considered unitary events. Our main conclusion is that both bursts and tonic spikes encode stimulus information efficiently, which rules out the hypothesis that bursts are nonvisual responses. (+info)
Role of semaphorin III in the developing rodent trigeminal system.
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Semaphorins are a large family of secreted and transmembrane glycoproteins. Sema III, a member of the Class III semaphorins is a potent chemorepulsive signal for subsets of sensory axons and steers them away from tissue regions with high levels of expression. Previous studies in mutant mice lacking sema III gene showed various neural and nonneural abnormalities. In this study, we focused on the developing trigeminal pathway of sema III knockout mice. We show that the peripheral and central trigeminal projections are impaired during initial pathway formation when they develop into distinct nerves or tracts. These axons defasciculate and compromise the normal bundling of nerves and restricted alignment of the central tract. In contrast to trigeminal projections, thalamocortical projections to the barrel cortex appear normal. Furthermore, sema III receptor, neuropilin, is expressed during a short period of development when the tract is laid down, but not in the developing thalamocortical pathway. Peripherally, trigeminal axons express neuropilin for longer duration than their central counterparts. In spite of projection errors, whisker follicle innervation appears normal and whisker-related patterns form in the trigeminal nuclei and upstream thalamic and cortical centers. Our observations suggest that sema III plays a limited role during restriction of developing trigeminal axons to proper pathways and tracts. Other molecular and cellular mechanisms must act in concert with semaphorins in ensuring target recognition, topographic order of projections, and patterning of neural connections. (+info)
Pre- and postsynaptic actions of opioid and orphan opioid agonists in the rat arcuate nucleus and ventromedial hypothalamus in vitro.
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1. Using whole-cell patch clamp recording from neurones in an in vitro slice preparation, we have examined opioid- and orphanin FQ (OFQ)-mediated modulation of synaptic transmission in the rat arcuate nucleus and ventromedial hypothalamus (VMH). 2. Application of OFQ activated a Ba2+-sensitive and inwardly rectifying K+ conductance in approximately 50 % of arcuate nucleus neurones and approximately 95 % of VMH neurones. The OFQ-activated current was blocked by the nociceptin antagonist [Phe1Psi(CH2NH)Gly2]-nociceptin(1-13) NH2 (NCA), a peptide that on its own exhibited only weak agonist activity at high concentrations (> 1 microM). Similar current activation was observed with the mu agonist DAMGO but not delta (DPDPE) or kappa (U69593) agonists. 3. In arcuate nucleus neurones, DAMGO (1 microM), U69593 (1 microM) and OFQ (100 nM to 1 microM) but not DPDPE (1 microM) were found to depress the amplitude of electrically evoked glutamatergic postsynaptic currents (EPSCs) and decrease the magnitude of paired-pulse depression, indicating that opioid receptors were located presynaptically. 4. In VMH neurones, DAMGO strongly depressed the EPSC amplitude in all cells examined. DAMGO decreased the magnitude of paired-pulse depression, indicating that mu receptors were located presynaptically. U69593 weakly depressed the EPSC while OFQ and DPDPE had no effect. 5. In VMH neurones, DAMGO depressed the frequency of miniature EPSCs (-58 %) in the presence of tetrodotoxin and Cd2+ (100 microM), suggesting that the actions of mu receptors could be mediated by an inhibition of the synaptic vesicle release process downstream of Ca2+ entry. 6. The data presented show that presynaptic modulation of excitatory neurotransmission in the arcuate nucleus occurs through mu, kappa and the orphan opioid ORL-1 receptors while in the VMH presynaptic modulation only occurs through mu opioid receptors. Additionally, postsynaptic mu and ORL-1 receptors in both the arcuate nucleus and VMH modulate neuronal excitability through activation of a K+ conductance. (+info)
Properties of C1 and other ventrolateral medullary neurones with hypothalamic projections in the rat.
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1. This study compared (i) the properties of C1 cells with those of neighbouring non-C1 neurones that project to the hypothalamus and (ii) the properties of C1 cells that project to the hypothalamus with those of their medullospinal counterparts. 2. Extracellular recordings were made at three rostrocaudal levels of the ventrolateral medulla (VLM) in alpha-chloralose-anaesthetized, artificially ventilated, paralysed rats. Recorded cells were filled with biotinamide. 3. Level I (0-300 microm behind facial nucleus) contained spontaneously active neurones that were silenced by baro- and cardiopulmonary receptor activation and virtually unaffected by nociceptive stimulation (firing rate altered by < 20 %). These projected either to the cord (type I; 36/39), or to the hypothalamus (type II; 2/39) but rarely to both (1/39). 4. Level II (600-800 microm behind facial nucleus) contained (i) type I neurones (n = 3) (ii) type II neurones (n = 11), (iii) neurones that projected to the hypothalamus and were silenced by baro- and cardiopulmonary receptor activation but activated by strong nociceptive stimulation (type III, n = 2), (iv) non-barosensitive cells activated by weak nociceptive stimulation which projected only to the hypothalamus (type IV, n = 9), (v) cells that projected to the hypothalamus and responded to none of the applied stimuli (type V, n = 7) and (vi) neurones activated by elevating blood pressure which projected neither to the cord nor to the hypothalamus (type VI, n = 4). 5. Level III (1400-1600 microm behind facial motor nucleus) contained all the cell types found at level II except type I. 6. Most of type I and II (17/26) and half of type III cells (4/8) were C1 neurones. Type IV-V were rarely adrenergic (2/12) and type VI were never adrenergic (0/3). 7. All VLM baroinhibited cells project either to the cord or the hypothalamus and virtually all (21/23) C1 cells receive inhibitory inputs from arterial and cardiopulmonary receptors. (+info)
Electrophysiological and morphological heterogeneity of rat dorsal vagal neurones which project to specific areas of the gastrointestinal tract.
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1. The electrophysiological properties of rat dorsal motor nucleus of the vagus (DMV) neurones (n = 162) were examined using whole cell patch clamp recordings from brainstem slices. Recordings were made from DMV neurones whose projections to the gastrointestinal tract had been identified by previously applying fluorescent retrograde tracers to the gastric fundus, corpus or antrum/pylorus, or to the duodenum or caecum. 2. The neuronal groups were markedly heterogeneous with respect to several electrophysiological properties. For example, neurones which projected to the fundus had a higher input resistance (400 +/- 25 Momega), a smaller and shorter after-hyperpolarization (16.7 +/- 0.49 mV and 63.5 +/- 3.9 ms) and a higher frequency of action potential firing (19.3 +/- 1.4 action potentials s-1) following injection of depolarizing current (270 pA) when compared with caecum-projecting neurones (302 +/- 22 Momega; 23. 5 +/- 0.87 mV and 81.1 +/- 5.3 ms; 9.7 +/- 1.1 action potentials s-1; P < 0.05 for each parameter). Differences between neuronal groups were also apparent with respect to the distribution of several voltage-dependent potassium currents. Inward rectification was present only in caecum-projecting neurones, for example. 3. Neurones (n = 82) were filled with the intracellular stain Neurobiotin allowing post-fixation morphological reconstruction. Neurones projecting to the caecum had the largest cell volume (5238 +/- 535 microm3), soma area (489 +/- 46 microm2) and soma diameter (24.6 +/- 1.24 microm) as well as the largest number of dendritic branch segments (23 +/- 2). 4. In summary, these results suggest that DMV neurones are heterogeneous with respect to some electrophysiological as well as some morphological properties and can be divided into subgroups according to their gastrointestinal projections. (+info)
Characteristics of mucosally projecting myenteric neurones in the guinea-pig proximal colon.
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1. Using retrograde tracing with 1,1'-didodecyl-3,3,3', 3'-tetramethylindocarbocyanine perchlorate (DiI) in combination with electrophysiological and immunohistochemical techniques we determined the properties of the putative intrinsic primary afferent myenteric neurones with mucosal projections in the guinea-pig proximal colon. 2. Eighty-four out of eighty-five DiI-labelled myenteric neurones were AH neurones with a late after-hyperpolarization. Thirty-three per cent of them exhibited atropine- and tetrodotoxin-resistant spontaneously occurring hyperpolarizing potentials (SHPs) during which the membrane resistance and excitability decreased. 3. DiI-labelled AH neurones had multipolar Dogiel type II morphology, primarily of the dendritic type. Sixty-one per cent of the neurones were immunoreactive for choline acetyltransferase (ChAT) and calbindin (Calb) and 23 % were ChAT positive but Calb negative. 4. DiI-labelled neurones did not receive fast excitatory postsynaptic potentials but 94 % (34/36) received slow excitatory postsynaptic potentials (sEPSPs). The neurokinin-3 (NK-3) agonist (MePhe7)-NKB but not the NK-1 agonist [(SAR9,Met(O2)11]-SP mimicked this response. The NK-3 receptor antagonist SR 142801 (1 microM) significantly decreased the amplitude and duration of the sEPSPs; the NK-1 receptor antagonist CP-99,994 (1 microM) was ineffective. Atropine (0.5 microM) increased the duration but not the amplitude of the sEPSPs. 5. Microejection of 100 mM sodium butyrate onto the neurones induced in 90 % of the DiI-labelled neurones a transient depolarization associated with an increased excitability. In neurones with SHPs sodium butyrate evoked, additionally, a late onset hyperpolarization. Perfusion of 0.1-10 mM sodium butyrate induced a dose-dependent increase in neuronal excitability. Sodium butyrate was ineffective when applied directly onto the mucosa. 6. Mucosally projecting myenteric neurones of the colon are multipolar AH neurones with NK-3-mediated slow EPSPs and somal butyrate sensitivity. (+info)
Characterization of a vertebrate neuromuscular junction that demonstrates selective resistance to botulinum toxin.
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Botulinum toxin blocks transmitter release by proceeding through a series of four steps: binding to cell surface receptors, penetration of the cell membrane by receptor-mediated endocytosis, penetration of the endosome membrane by pH-induced translocation, and intracellular proteolysis of substrates that govern exocytosis. Each of these steps is essential for toxin action on intact cells. Therefore, alterations in cell structure or cell function that impede any of these steps should confer resistance to toxin. In the present study, screening for susceptibility to four serotypes of botulinum toxin revealed that the cutaneous-pectoris nerve-muscle preparation of Rana pipiens is resistant to type B botulinum toxin. Resistance was demonstrated both by electrophysiologic techniques and by dye-staining techniques. In addition, resistance to serotype B was demonstrated at toxin concentrations that were 2 orders of magnitude higher than those associated with blockade produced by other serotypes. In experiments on broken cell preparations, type B toxin cleaved synaptobrevin from frog brain synaptosomes. However, the toxin did not bind to frog nerve membranes. These findings suggest that resistance is due to an absence of cell surface receptors for botulinum toxin type B. The fact that cutaneous-pectoris preparations were sensitive to other botulinum toxin serotypes (A, C, and D), as well as other neuromuscular blocking agents (alpha-latrotoxin, beta-bungarotoxin), indicates that botulinum toxin type B receptors are distinct. (+info)