Spontaneous activity induced in isolated mouse spinal cord by high extracellular calcium and by low extracellular magnesium

Primary afferent terminals acting as excitatory interneurons contribute to spontaneous motor activities in the immature spinal cord

Patterned, spontaneous activity plays a critical role in the development of neuronal networks. A robust spontaneous activity is observed in vitro in spinal cord preparations isolated from immature rats. The rhythmic ventral root discharges rely mainly on the depolarizing/excitatory action of GABA and glycine early during development, whereas at later stages glutamate drive is primarily responsible for the rhythmic activity and GABA/glycine are thought to play an inhibitory role. However, rhythmic discharges mediated by the activation of GABA(A) receptors are recorded from dorsal roots (DRs). In the present study, we used the in vitro spinal cord preparation of neonatal rats to identify the relationship between discharges that are conducted antidromically along DRs and the spontaneous activity recorded from lumbar motoneurons. We show that discharges in DRs precede those in ventral roots and that primary afferent depolarizations (PADs) start earlier than EPSPs in motoneurons. EPSP-triggered averaging revealed that the action potentials propagate not only antidromically in the DR but also centrally and trigger EPSPs in motoneurons. Potentiating GABAergic antidromic discharges by diazepam increased the EPSPs recorded from motoneurons; conversely, blocking DR bursts markedly reduced these EPSPs. High intracellular concentrations of chloride are maintained in primary afferent terminals by the sodium-potassium-chloride cotransporter NKCC1. Blocking these cotransporters by bumetanide decreased both dorsal and ventral root discharges. We conclude that primary afferent fibers act as excitatory interneurons and that GABA, through PADs reaching firing threshold, is still playing a key role in promoting spontaneous activity in neonates.

Role of glutamate in locomotor rhythm generating neuronal circuitry

Central pattern generators (CPGs) are defined as neuronal circuits capable of producing a rhythmic and coordinated output without the influence of sensory input. The locomotor and respiratory neuronal circuits are two of the better-characterized CPGs, although much work remains to fully understand how these networks operate. Glutamatergic neurons are involved in most neuronal circuits of the nervous system and considerable efforts have been made to study glutamate receptors in nervous system signaling using a variety of approaches. Because of the complexity of glutamate-mediated signaling and the variety of receptors triggered by glutamate, it has been difficult to pinpoint the role of glutamatergic neurons in neuronal circuits. In addition, glutamate is an amino acid used by every cell, which has hampered identification of glutamatergic neurons. Glutamatergic excitatory neurotransmission is dependent on the release from glutamate-filled presynaptic vesicles loaded by three members of the solute carrier family, Slc17a6-8, which function as vesicular glutamate transporters (VGLUTs). Recent data describe that Vglut2 (Slc17a6) null mutant mice die immediately after birth due to a complete loss of the stable autonomous respiratory rhythm generated by the pre-Bötzinger complex. Surprisingly, we found that basal rhythmic locomotor activity is not affected in Vglut2 null mutant embryos. With this perspective, we discuss data regarding presence of VGLUT1, VGLUT2 and VGLUT3 positive neuronal populations in the spinal cord.

Long-range oscillatory Ca2+waves in rat spinal dorsal horn

Synchronous activity of large populations of neurons shapes neuronal networks during development. However, re-emergence of such activity at later stages of development could severely disrupt the orderly processing of sensory information, e.g. in the spinal dorsal horn. We used Ca2+ imaging in spinal cord slices of neonatal and young rats to assess under which conditions synchronous activity occurs in dorsal horn. No spontaneous synchronous Ca2+ transients were detected. However, increasing neuronal excitability by application of 4-aminopyridine after pretreatment of the slice with blockers of (RS)-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate, gamma-aminobutyric acid (GABA)(A) and glycine receptors evoked repetitive Ca2+ waves in dorsal horn. These waves spread mediolaterally with a speed of 1.0 +/- 0.1 mm/s and affected virtually every dorsal horn neuron. The Ca2+ waves were associated with large depolarizing shifts of the membrane potential of participating neurons and were most likely synaptically mediated because they were abolished by blockade of action potentials or N-methyl-D-aspartate (NMDA) receptors. They were most pronounced in the superficial dorsal horn and absent from the ventral horn. A significant proportion of the Ca2+ waves spread to the contralateral dorsal horn. This seemed to be enabled by disinhibition as primary afferent-induced dorsal horn excitation crossed the midline only when GABA(A) and glycine receptors were blocked. Interestingly, the Ca2+ waves occurred under conditions where AMPA/kainate receptors were blocked. Thus, superficial dorsal horn NMDA receptors are able to sustain synchronous neuronal excitation in the absence of functional AMPA/kainate receptors.

Epileptiform activity in rat spinal dorsal horn in vitro has common features with neuropathic pain

Neuropathic pain and epileptic seizures bear several similarities, among them is the response to anticonvulsant drugs. It has therefore been hypothesized that epileptiform activity of nociceptive spinal dorsal horn neurons may contribute to paroxysmal forms of neuropathic pain. We used patch-clamp and field potential recordings from young rat spinal cord slices to test if nociceptive dorsal horn structures are indeed able to sustain epileptiform activity. Application of the convulsant 4-aminopyridine (100 microM) evoked epileptiform activity that was most pronounced in superficial dorsal horn and involved nociceptive lamina I neurons with a projection to the brain. The epileptiform activity was dependent on fast excitatory and inhibitory synaptic transmission through ionotropic glutamate receptors and GABA(A) receptors. During epileptiform activity, previously silent polysynaptic pathways from primary afferent C-fibers to superficial dorsal horn neurons were opened. Stimulation of primary afferents at Adelta- and C-fiber intensity interfered with the epileptiform rhythm, suggesting that both affect the same dorsal horn structures. Similar to neuropathic pain, spinal dorsal horn epileptiform activity was much less reduced by classical analgesics than by anticonvulsant agents.

Effects of extracellular calcium and magnesium on central respiratory control in the brainstem-spinal cord of neonatal rat

The influence of extracellular Ca2+ and Mg2+ concentrations ([Ca2+]ECF and [Mg2+]ECF, respectively) on central respiratory control was analyzed using the isolated brainstem-spinal cord of the neonatal rat. Central respiratory activity was recorded from the C4 ventral roots. The depth profile of [Ca2+]ECF below the ventral medullary surface was measured with ion-sensitive electrodes. The gradient in [Ca2+]ECF disappeared about 1 h after changing superfusate Ca2+ ([Ca2+]CSF) from 2 to 0.5 mM, but not even in 2 h after switching to Ca2+-free superfusate. High [Ca2+]CSF (4 mM) or high [Mg2+]CSF (4, 8 mM) decreased respiratory frequency (fR), whereas low [Ca2+]CSF (0.5 mM) increased fR and augmented the respiratory CO2 responsiveness. High [Ca2+]CSF as well as low [Mg2+]CSF (0.5 mM) disturbed respiratory rhythm and pattern, which were markedly restored by high CO2. The depressing effect of high [Ca2+]ECF and the stimulating effect of low [Ca2+]ECF on the medullary neuronal activity were confirmed by perforated patch recordings. These results suggest that [Ca2+]ECF and [Mg2+]ECF determine the excitability of the respiratory neuron network by modulating the neuronal surface potential, transmembrane Ca2+ influx, Ca2+-sensitive cation channel gating, and synaptic transmission. Furthermore, some of these actions appear to be antagonized by CO2/H+.

Comparison of spontaneous motor pattern generation in non-hemisected and hemisected mouse spinal cord

Spontaneous electromyogram (EMG) patterns in the gastrocnemius (G) and tibialis anterior (TA) muscles of spinal cord-hindlimb explants from neonatal mice were investigated. Compared to non-hemisected explants, neither longitudinal hemisection of the spinal cord nor hemisection plus transection at L1 significantly altered the incidence of spontaneous motor rhythm. Therefore, not only does each half of the neonatal spinal cord contain sufficient circuitry to generate motor rhythm, but the more reduced preparations were just as likely to produce such activity. Hemisected preparations, however, exhibited slower rhythm, perhaps due to the loss of excitatory commissural connections. No correlation was found between the number of cycles in a rhythmic sequence and cycle period. In hemisected as well as non-hemisected explants, sequences of spontaneous EMG rhythm occurred in either the G or TA muscle, but not in both muscles simultaneously. Consequently, cycle-to-cycle alternation between rhythmic bursting in the G and TA muscles was not observed. The excitability in such preparations was apparently insufficient for maintained activations of both muscles (either for cycle-to-cycle alternation or for co-contraction).

Hypoxic failure of synaptic transmission in the isolated spinal cord, and the effects of divalent cations

Responses evoked by stimulation of a dorsal root were recorded from ventral and dorsal roots of isolated spinal cords of infant mice. Interstitial potassium, [K+]o, and extracellular DC voltage were recorded from dorsal gray matter in some experiments. When oxygen was withdrawn, synaptically transmitted discharges (dorsal horn response, DHR, and monosynaptic ventral root reflex, VRR) began to be depressed within a minute, and were depressed to less than 30% of control amplitude in 10-15 min. Responses recovered fully if oxygen was readmitted within 45 min, but no recovery was seen after 90 min of hypoxia. The degree of the depression of VRR was as expected from the depression of the electrotonically conducted excitatory postsynaptic potential (VRepsp). Responses failed much more rapidly in spinal cords of 15-16-day-old mice, than of 9-14-day-olds. When the spinal cord was bathed in elevated [Ca2+]o or in reduced [Mg2+]o, synaptic transmission was consistently maintained for a longer period of hypoxia than in bathing fluid of normal cation content. In a sizeable minority of the trials during hypoxia an abrupt increase of [K+]o occurred, accompanied by a sudden negative shift of extracellular potential, closely resembling spreading depression (SD) of forebrain structures. Delayed post-hypoxic spontaneous activity was seen in many spinal cords. The results are compatible with the hypothesis that hypoxic failure of synaptic transmission is due, in part or whole, to blockade of inward Ca2(+)-current in presynaptic terminals. Cells in spinal gray matter can no longer be regarded as 'immune' to SD-like depolarization, but the limited conditions under which SD can occur are not yet clear.

Spinal dorsal horn neurons in elevated extracellular calcium: cell properties and spontaneous discharges

Recordings were made from neurons in the dorsal horn (DH), and from dorsal and ventral roots (DRs and VRs) of isolated spinal cords of infant mice. Raising calcium concentration ([Ca2+]) in the organ bath from 1.2 to 2.4 mmol/l resulted in a slight hyperpolarization, elevation of threshold current (rheobase), and augmentation of excitatory postsynaptic potentials (EPSPs). In many cells EPSPs acquired a much prolonged late phase. Orthodromic stimulation evoked in some DH neurons an action potential that had the same threshold as, and coincided in time with, the 'dorsal horn response' (DHR) recorded from DR. In spinal cords bathed in elevated [Ca2+], DR recordings showed irregularly recurring spontaneous waves, and DH neurons generated spontaneous EPSPs, often with spikes. Some neurons fired irregularly timed spontaneous action potentials that did not appear triggered by EPSPs. In less than 50% of the neurons the spontaneous EPSPs coincided in time with the spontaneous DR waves. The action potentials that appeared without EPSP were fired independently from DR activity. These observations confirm that elevation of interstitial free calcium concentration results in strong enhancement of excitatory transmission, especially of an EPSP of much extended duration. Virtually all neurons showed increased spontaneous activity in high [Ca2+], but only a minority appeared recruited into the synchronized discharges that are detectable as spontaneous waves in DR and VR recordings.