A GABAergic Maf-expressing interneuron subset regulates the speed of locomotion in Drosophila.

Interneurons (INs) coordinate motoneuron activity to generate appropriate patterns of muscle contractions, providing animals with the ability to adjust their body posture and to move over a range of speeds. In Drosophila larvae several IN subtypes have been morphologically described and their function well documented. However, the general lack of molecular characterization of those INs prevents the identification of evolutionary counterparts in other animals, limiting our understanding of the principles underlying neuronal circuit organization and function. Here we characterize a restricted subset of neurons in the nerve cord expressing the Maf transcription factor Traffic Jam (TJ). We found that TJ+ neurons are highly diverse and selective activation of these different subtypes disrupts larval body posture and induces specific locomotor behaviors. Finally, we show that a small subset of TJ+ GABAergic INs, singled out by the expression of a unique transcription factors code, controls larval crawling speed.

An activity-dependent neurotrophin-3 autocrine loop regulates the phenotype of developing hippocampal pyramidal neurons before target contact.

Neurotrophin-3 (NT-3), its cognate receptor trkC, and voltage-gated calcium channels are coexpressed by embryonic pyramidal neurons before target contact, but their functions at this stage of development are still unclear. We show here that, in vitro, anti-NT-3 and anti-trkC antibodies blocked the increase, and NT-3 reversed the decrease in the number of calbindin-D(28k)-positive pyramidal neurons induced by, respectively, calcium channel activations and blockades. Similar results were obtained with single-neuron microcultures. In addition, voltage-gated calcium channel inhibition downregulates the extracellular levels of NT-3 in high-density cultures. Moreover, electrophysiological experiments in single-cell cultures reveal a tetrodotoxin-sensitive spontaneous electrical activity allowing voltage-gated calcium channel activation. The mouse NT-3 (-/-) mutation decreases by 40% the number of developing calbindin-D(28k)-positive pyramidal neurons, without affecting neuronal survival, both in vitro and in vivo. Thus, present results strongly support that an activity-dependent autocrine NT-3 loop provides a local, intrinsic mechanism by which, before target contact, hippocampal pyramidal-like neurons may regulate their own differentiation, a role that may be important during early CNS differentiation or after adult target disruption.

Molecular diversity of voltage-gated sodium channel alpha subunits expressed in neuronal and non-neuronal excitable cells.

In order to investigate the role of molecular diversity of voltage-activated sodium channel alpha-subunits in excitability of neuronal and non-neuronal cells, we carried out patch-clamp recordings and single-cell RT-PCR on two different types of mammalian excitable cells i.e. hippocampal neurons and non-neuronal utricular epithelial hair cells. In each cell type, multiple different combinations of sodium channel alpha-subunits exist from cell to cell despite similar sodium current properties. The mRNA isoforms, Nav1.2 and Nav1.6, are the most frequently detected by single cell analysis in the two cell types while Nav1.3 and Nav1.7 are also moderately expressed in embryonic hippocampal neurons and in neonatal utricular hair cells respectively. By investigating the particular alternate splice isoforms of Nav1.6 occurring at the exon 18 of the mouse orthologue SCN8A, we revealed that this subunit co-exist in the two cell types under different alternative spliced isoforms. The expression of non-functional isoforms of Nav1.6 in utricular epithelial hair cells excludes the involvement of this subunit in supporting their excitability. Thus, from a functional point of view, the present results suggest that, at the single cell level, both neuronal and non-neuronal excitable cells expressed different and complex patterns of sodium channel gene transcripts but this diversity alone cannot explain the sodium current properties of these cell types.

Diversity of voltage-gated calcium currents in large diameter embryonic mouse sensory neurons.

Voltage-gated Ca2+ currents were investigated in a subpopulation of dorsal root ganglion neurons (large diameter, neurofilament-positive) acutely isolated from 13-day-old mouse embryos and recorded using the whole-cell patch-clamp technique. Low- and high-voltage-activated calcium currents were recorded. These currents could be identified and separated by their distinct (i) threshold of activation, (ii) ability to run-up during the early phase of recording and (iii) decay kinetics using Ba2+ instead of Ca2+ as the charge carrier. Among high-voltage-activated currents, L-, N- and P-type Ca2+ currents were identified by their sensitivity to, respectively, the dihydropyridine agonist Bay K 8644 (5 microM) and antagonist nitrendipine (3 microM), omega-conotoxin GVIA (3 microM) and omega-agatoxin IVA (30 nM). In the combined presence of nitrendipine (3 microM), omega-conotoxin GVIA (3 microM) and omega-agatoxin IVA (30 nM), two additional high-voltage-activated components were detected. One, blocked by 500 nM omega-conotoxin MVIIC and 1 microM omega-agatoxin IVA, had properties similar to those of the Q-type Ca2+ current first reported in cerebellar granule cells. The other, defined by its resistance to saturating concentrations of all the blockers mentioned above applied in combination, resembles the R-type Ca2+ current also described in cerebellar granule cells. In conclusion, embryonic sensory neurons appear to express a large repertoire of voltage-activated Ca2+ currents with distinct pharmacological properties. This diversity suggests a great variety of pathways for Ca2+ signaling which may support different functions during development.

Calcium channel subtypes responsible for voltage-gated intracellular calcium elevations in embryonic rat motoneurons.

The central role of electrical activity and Ca2+ influx in motoneuron development raises important questions about the regulation of Ca2+ signalling induced by voltage-dependent Ca2+ influx. In the purified embryonic rat motoneuron preparation, we recorded barium currents through voltage-activated Ca2+ channels using the whole-cell configuration of the patch-clamp technique. We found that motoneurons express at least four types of high-voltage-activated Ca2+ channels, based on their kinetics, voltage-dependences and pharmacological properties. Of the sustained Ca2+ current activated at 0 mV from a holding potential of -100 mV, approximately 45% was omega-conotoxin-GVIA (1 microM) sensitive, 25% was omega-agatoxin-IVA (30 nM) sensitive and 20% was nitrendipine (250 nM) sensitive. The residual current, after applying these three antagonists, was an inactivating current that differs from classical T-type Ca2+ currents. Based on this pharmacology, changes in intracellular free Ca2+ concentrations were then monitored by Fura 2 digital imaging microspectrofluorimetry. Upon K+ depolarization, the intracellular Ca2+ transient induced by the activation of each type of Ca2+ channel appeared to be quantitatively proportional to their Ca2+ influx. The existence of a calcium-induced calcium release mechanism through activation of caffeine-, ryanodine-sensitive intracellular stores was then investigated. High doses of caffeine and low doses of ryanodine failed to increase intracellular free calcium concentrations and low concentrations of caffeine and high concentrations of ryanodine did not affect K+-induced intracellular free calcium concentration transients indicating both the absence of Ca2+-gated Ca2+-release channels and of a Ca2+-induced Ca2+ release mechanism. Together, these data provide evidence that embryonic motoneurons express multiple Ca2+ channels that function as important regulators of intracellular Ca2+ signalling and may be involved in their development.

Multiple voltage-dependent calcium currents in acutely isolated mouse vestibular neurons.

We investigated the presence of voltage-gated calcium currents in vestibular neurons acutely isolated from postnatal mice vestibular ganglions using the whole-cell patch-clamp technique. The neuronal origin of the recorded cells was confirmed by immunohistochemical detection of neurofilaments and calretinin. High and low voltage-activated calcium currents were recorded. High voltage-activated currents were present in all investigated neurons. Low voltage-activated currents were recorded in only a few large vestibular neurons. High and low voltage-activated currents were distinguished by their thresholds of activation and their ability to run-up during early recordings. Among high voltage-activated currents. L-, N- and P-type currents were identified by their sensitivity to, respectively, the dihydropyridines agonist Bay K 8644 (3 microM) and antagonist nitrendipine (3 microM), the co-conotoxin GVIA (3 microM) and the omega-agatoxin IVA at low concentration (50 nM). An inactivating current sensitive to 1 microM omega-agatoxin IVA with characteristics similar to those of the Q-type current was also recorded in vestibular neurons. When L-, N-, P-, Q-type barium currents were blocked, a residual high voltage-activated current defined by its resistance to saturating concentrations of all above blockers was detected. This residual current was completely blocked by 0.5 mM nickel and cadmium. Our results reveal that primary vestibular neurons express a variety of voltage-activated calcium currents with distinct physiological and pharmacological properties. This diversity could be related both with their functional synaptic characteristic, and with the intrinsic physiological properties of each class of vestibular afferents.

Toxin-resistant calcium currents in embryonic mouse sensory neurons.

We characterized toxin-insensitive calcium currents expressed by acutely dissociated embryonic dorsal root ganglion neurons. In the presence of 3 microM omega-conotoxin-GVIA, 3 microM nitrendipine and either 500 nM omega-agatoxin-IVA or 500 nM omega-conotoxin-MVIIC to inhibit N-, L- and P/Q-type currents, respectively, all neurons expressed two residual currents: a T-type and another which we referred to as toxin-resistant current. The toxin-resistant current (i) consisted of an inactivating and a sustained components, (ii) had a threshold of activation and a steady-state inactivation comprised between that of the T-type current and that of the other high-voltage-activated currents, (iii) had the same permeability for barium and calcium used as charge carriers, (iv) was highly sensitive to both cadmium and nickel; and (v) was insensitive to 500 microM amiloride which abolished the T-type at this concentration. The properties of the toxin-resistant current are very similar to those of the currents expressed in oocytes following injection of alpha(1E) subunits which we demonstrated to be present in these neurons. Therefore a component of the toxin-resistant current calcium channels in sensory neurons may be closely related to those calcium channels formed by alpha(1E) subunits.

Early postnatal muscle contractile activity regulates the carbonic anhydrase phenotype of proprioceptive neurons in young and mature mice: evidence for a critical period in development.

Carbonic anhydrase activity, a marker of mouse proprioceptive neurons in adult dorsal root ganglia, is first detectable in the perinatal period, increases until postnatal day 60 and remains stable in adulthood. The onset of carbonic anhydrase staining begins after the neurons have made connections with their targets suggesting that neuron-target interactions regulate carbonic anhydrase phenotype development. To examine this possibility, we first analysed carbonic anhydrase expression in mdx mice which are characterized by a massive but reversible degeneration of skeletal muscle concomitant with the carbonic anhydrase ontogenesis. Neuronal carbonic anhydrase expression in mdx mice stopped developing when the period of muscular degeneration-regeneration began. Furthermore this alteration persisted during adulthood. We then analysed carbonic anhydrase expression in fifth lumbar dorsal root ganglion of developing control mice before and after surgical procedures that might interfere with central and peripheral target influences on dorsal root ganglion neurons. Central disconnection (dorsal rhizotomy) did not affect the development of carbonic anhydrase activity. Disrupting neuron-peripheral target interactions by sciatic nerve transection or blocking muscle contraction by tenotomy stopped the development of neuronal carbonic anhydrase content. Finally, recovery was monitored following sciatic nerve crush. In adults, recovery of carbonic anhydrase activity was obtained after functional recuperation; similar manipulations during the first month of life induced irreversible alteration of the carbonic anhydrase phenotype. These results show that the development of carbonic anhydrase activity in proprioceptive neurons is regulated by neuron-muscle interactions (i.e. muscle contraction). They also provide evidence for a critical period in the development of the carbonic anhydrase phenotype. We suggest that these two mechanisms are responsible for the altered carbonic anhydrase phenotype of the dorsal root ganglion neurons in mdx mice, a model of human muscular dystrophy.

The alpha(1A) subunits of rat brain calcium channels are developmentally regulated by alternative RNA splicing.

Calcium influx through voltage-gated calcium channels governs important aspects of CNS development. Multiple alternative splicings of the pore-forming alpha(1) subunits have been evidenced in adult brain but little information about their expression during ontogenesis is presently available. The aim of this study was to focus on the expression of three rat voltage-gated calcium channel alpha(1A) splice variants (alpha(1A-a), alpha(1A-b) and alpha(1A-EFe)) during brain ontogenesis in vivo. Using a reverse transcription-polymerase chain reaction strategy, we found that the three isoforms have different timings of development throughout the brain: alpha(1A-b) is expressed from embryonic to the adult stage, alpha(1A--EFe) is restricted to the embryonic period whereas alpha(1A-a) is expressed only postnatally. In situ hybridization indicated that alpha(1A-a) and alpha(1A-b) isoforms develop with different regional and cellular patterns. In hippocampus and cerebellum, alpha(1A-b) represented the predominant isoform at all developmental stages. Taken together, these data reveal that alternative RNA splicing may modulate the alpha(1A) calcium channel properties during development.

Opposite developmental regulation of P- and Q-type calcium currents during ontogenesis of large diameter mouse sensory neurons.

Analysis of neuronal development has emphasized the importance of voltage-activated Ca2+ currents during the initial period of differentiation. We investigated non-N, non-L Ba2+ currents through Ca2+ channels in freshly dissociated large diameter embryonic mouse dorsal root ganglion neurons using the whole-cell patch-clamp technique. Two types of omega-agatoxin IVA-sensitive currents were clearly distinguished at embryonic day 13: a sustained P-type current blocked selectively at 30 nM (IC50 = 3nM) and an inactivating Q-type current blocked in the range 50-500 nM (IC50 = 120nM). The P-type Ca2+ current disappeared at day 15 whereas the Q-type Ca2+ current increased two- to three-fold during the same embryonic period. In contrast, the contribution of the non-L, non-N, omega-agatoxin IVA-resistant current (R-type) was constant during this developmental span. In conclusion, our results clearly show that P- and Q-type Ca2+ currents are differentially expressed during ontogenesis in large diameter dorsal root ganglion neurons. The developmental change, which occurs during the period of target innervation, could be related to specific key events such as natural neuron death and onset of synapse formation.

Voltage-activated sodium currents in acutely isolated mouse vestibular ganglion neurones.

Voltage-activated sodium currents (INa) in vestibular ganglion neurones acutely isolated from postnatal mice were investigated using the whole-cell configuration of the patch-clamp technique. Under recording conditions designed to allow the complete isolation of INa depolarizations from a holding potential of -80 mV revealed a fast inactivating inward current which was activated around -60 mV and exhibited maximum peak current around -30 mV. This current was eliminated when the cells were perifused with a Na(+)-free solution and almost totally blocked by application of 100 nM tetrodotoxin (TTX). These properties identify this inward current as TTX-sensitive INa. The half-maximum activation potential of INa was -46 mV and its half-maximum inactivation potential was -69 mV. This is the first report of voltage-activated sodium currents in vestibular primary neurones.

Hyperpolarization-activated (Ih) current in mouse vestibular primary neurons.

The presence of a hyperpolarization-activated inward current (Ih) was investigated in mouse vestibular primary neurons using the whole-cell patch-clamp technique. In current-clamp configuration, injection of hyperpolarizing currents induced variations of membrane voltage with prominent time-dependent rectification increasing with current amplitudes. This effect was abolished by 2 mM Cs+ or 100 microM ZD7288. In voltage-clamp configuration, hyperpolarization pulses from -60 mV to -140 mV triggered a slow activating and non inactivating inward current that was sensitive to the two blockers, but insensitive to 5 mM Ba2+. Changing Na+ and K+ concentrations demonstrated that Ih current is carried by both these monovalent cations. This is the first demonstration of a Ih current in vestibular primary neurons.

Skeletal muscle contraction modulates carbonic anhydrase phenotype in adult mouse dorsal root ganglion neurons.

Recently carbonic anhydrase (CA) activity was demonstrated in adult mammalian proprioceptive neurons of the lumbar dorsal root ganglion (DRG). To assess if neuron-target interactions govern the neuronal CA phenotype, we examined how various experimental procedures which modify the interactions of these neurons with their central and peripheral targets, affect mouse L5 lumbar DRG CA activity. In normal mice and under central disconnection, carbonic anhydrase activity was detected in 30% of neurons. One day after sciatic nerve transaction the percentage of CA-positive neurons decreased to around 50% of that in controls, although both the total number of neurons per ganglion and glial CA content were unchanged. The pattern of CA activity then remained stable until at least 30 days post-operative. All experimental procedures used to block muscle contraction, including ventral rhizotomy, tenotomy, local application to the nerve of both tetrodotoxin and lidocaine or intramuscular injection of the botulinum toxin, produced a significant decrease in neuronal CA staining. Moreover, axonal transport block by vinblastine induced a decrease in CA-positive neurons. These results show that functional neuron-muscle interactions independent of DRG-spinal Cord influences contribute to the regulation of CA activity in lumbar DRG neurons. This modulation could be under the control of unidentified activity-dependent molecular mechanism involving stimuli through the skeletal muscle contraction, inducing in turn, the synthesis of a CA-regulating factor(s) retrogradely transported to the neuronal cell body and/or nuclei.

Embryonic rat motoneurons express a functional P-type voltage-dependent calcium channel.

Only L- and N-type high voltage-activated calcium currents (HVA ICa) have been demonstrated in identified embryonic spinal motoneurons. However, pharmacological experiments suggest that other HVA ICa, including P-type, govern neurotransmitter release at the adult neuromuscular junction. We sought to analyse if embryonic motoneurons express these other ICa, using the whole-cell voltage-clamp method on motoneurons purified by a new metrizamide-panning technique from E15 rat embryos. In addition to L-type dihydropyridine-sensitive and N-type omega-GVIA-sensitive currents, motoneurons express two other HVA ICa. One has properties related to the P-type channel currents described in Purkinje cells: it is inhibited by the peptide omega-agatoxin-IVA with a maximal effect at 100-200 nM. The inhibited current has a characteristic sustained component during depolarizing test pulses. Furthermore, 50-100 nM concentrations of omega-agatoxin-IVA reduce the increase in cytoplasmic calcium concentration observed after depolarization. The other HVA ICa is resistant to saturating concentrations of verapamil, omega-conotoxin GVIA and omega-agatoxin-IVA which block L, N and P-type HVA ICa, respectively. These results suggest that it is now possible to dissect, using a simple method of purification, the properties of the ICa in embryonic mammalian motoneurons and to provide pharmacological evidence for multiple calcium channels which may be involved in regulation of their activity during development.

Large unit conductance voltage chloride channels are expressed in mouse neural crest cells and embryonic dorsal root ganglion cells.

The early expression of voltage-activated chloride channels of large unitary conductance (450 pS in symmetrical 140 mM KCl) was demonstrated using patch-clamp techniques in two preparations: (i) neural crest cells isolated from 9-day-old (E9) mouse embryos and (ii) acutely isolated dorsal root ganglion cells isolated from E12 mouse embryos. Properties of these ionic channels have been analyzed using single channel recordings and the group mean of these single channels.

Developmental regulation of carbonic anhydrase expression in mouse dorsal root ganglia.

The development of proprioceptive neurons in mammalian dorsal root ganglia (DRG) remains poorly documented since few specific markers for these neurons are known. Recent studies suggest that carbonic anhydrase (CA) is a specific marker of this functionally defined neuronal population. The present study was designed to investigate the development of CA staining in sensory neurons. We investigated CA reactivity in mouse lumbar DRGs from embryonic day 13 (E13) to postnatal day 100 (P100) using a modified cytoenzymatic Hansson method. Neuronal CA reactivity was first detected during the perinatal stage (1-3% of DRG neurons) and increased progressively from P0 to P60 when it reached a plateau (about 30-33% of DRG neurons). Statistical morphometric analysis was used to define whether CA staining identifies the same population(s) during development. The results demonstrated that, whatever the stage of development, reactive neuronal cells are included in the well-defined large type A population. The possibility that neuronal CA expression is a reliable marker of the 'functional activity' of the proprioceptive neurons in mammals is discussed. The late development expression of the enzyme (after target innervation) raises the possibility of a regulation of the CA phenotype by neuron-target interactions.

Skeletal muscle extracts promote the survival of neurofilament-positive mammalian sensory neurons.

Cultured neurons of the mammalian dorsal root ganglia (DRG) can be divided, as in intact ganglia, into two classes: 'large light' (neurofilament-positive) and 'small dark' (neurofilament-negative) neurons. While 'small dark' neuron survival depends on NGF during ontogenesis, little is known about the neurotrophic factor requirement of the 'large light' sub-population. This study demonstrates that the in vitro survival of neonatal mammalian neurofilament-positive DRG neurons requires the presence of a neurotrophic factor present in skeletal muscle extract.

Rat embryonic hippocampal neurons express a new class A calcium channel variant.

The aim of this study was to investigate, using a RT-PCR strategy, rat voltage-gated class A calcium channel (alpha1A) splice variants during rat hippocampus development. Results demonstrate the presence of multiple alpha1A mRNAs with the hippocampus formation and revealed a new variant of the rat alpha1A subunit (alpha1A-EFe) that diverges from alpha1A-a in the EF-hand domain. alpha1A-EFe expression in hippocampal neurons is restricted to the embryonic period. This in vivo developmental program is recapitulated in dissociated cultures of E17 embryonic hippocampal neurons. These data demonstrate that rat hippocampus neurons express a unique alpha1A splice variant during the embryonic period and suggest that alternative RNA splicing may modulate neuronal calcium channel properties during development.

Inward potassium rectifier current in type I vestibular hair cells isolated from guinea pig.

Large inward current activated by hyperpolarization was studied using whole cell patch clamp technique in type I vestibular hair cells of guinea pig. Near the resting membrane potential, at an holding potential of -60 mV (HP -60), this current increased with hyperpolarizing steps and showed time-dependent decay for steps below -80 mV. This current was progressively inactivated at more negative holding potential and was totally abolished at HP -90 mV. The underlying conductance was a K+ conductance as indicated by: (i) its dependence on the external potassium concentration; (ii) its tail currents, which reversed at about -90 mV in solutions with a normal gradient for K+ ions. Pharmacological studies revealed that external application of 4-aminopyridine (5 mM) reversibly blocked (95%) the total inward current, while external application of tetraethylammonium (10 mM) or cesium (2 mM) did not significantly affect the amplitude of this current. This potassium inward rectifier current could contribute to restoration of the resting membrane potential during negative stimulations.

Inhibition of T-type calcium currents by dihydropyridines in mouse embryonic dorsal root ganglion neurons.

The effects of dihydropyridines (DHPs) normally considered to be specific for L-type calcium channels were studied on the T-type Ca channel current of acutely isolated dorsal root ganglion (DRG) neurons taken from 13-day-old (E13) mouse embryos. Potent but reversible inhibitory effects of the DHP nicardipine were found in the micromolar range. For example, 5 microM nicardipine suppressed 93 +/- 5% of T-type currents. In comparison, other classical DHPs such as nifedipine, PN 200-110 and nitrendipine had only weak effects (less than 20% inhibition) at the same concentration. The inhibition by nicardipine was found slightly to be voltage dependent and the drug induced a leftward shift in the steady-state inactivation. The DHP agonist (-)-Bay K 8644, which dramatically increased the L-type current, weakly decreased T-type Ca currents (17 +/- 8% at 5 microM). In conclusion, neuronal T-type Ca channels may be potential targets for some dihydropyridines. This property is not only a feature of the central nervous system (J. Physiol., 412 (1989) 181-195) and can be extended to peripheral neurons.