Perfusion of frog's spinal cord as a convenient method for neuropharmacological studies

Potentiation of excitatory postsynaptic potentials by a metabotropic glutamate receptor agonist (1S,3R-ACPD) in frog spinal motoneurons

We conducted intracellular recordings of lumbar motoneurons in the arterially-perfused frog spinal cord and investigated the effects of a metabotropic glutamate receptor agonist, (1S,3R)-1-aminocyclopentane-1,3-dicarboxylic acid (ACPD), on excitatory postsynaptic potentials evoked by stimulation of the descending lateral column fibers (LC-EPSPs). In the absence of Mg2+, ACPD reversibly potentiated the amplitude of monosynaptic LC-EPSPs by more than 15% in 15 of 19 cells with 5 microM ACPD and in 7 of 12 cells with 0.5 microM ACPD. The EPSP amplitudes with 5 and 0.5 microM ACPD were 142 +/- 10% (mean +/- S.E.M., n = 19) and 130 +/- 13% (n = 12) of the controls. The potentiation was seen without a decrease in the input conductance. Glutamate-induced depolarizations in the absence and the presence of 0.5 microM ACPD were not significantly different in cells perfused with the low Ca(2+)-high Mg2+ solution which eliminated chemical transmission. Paired pulse facilitation of LC-EPSPs was reversibly decreased in association with the potentiation. ACPD-induced potentiation of monosynaptic LC-EPSPs was seen in 5 of 6 cells in the presence of D-(-)-2-amino-5-phosphonopentanoic acid (D-AP5), an NMDA receptor antagonist. ACPD occasionally activated polysynaptic components of LC-EPSPs which were mediated mainly via NMDA receptors. On the other hand, ACPD-induced potentiation of EPSPs was inhibited by extracellular Mg2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Enhancement of monosynaptic excitatory postsynaptic potentials by glutamate in frog spinal motoneurons

We analyzed glutamate-induced enhancement of the amplitude of monosynaptic excitatory postsynaptic potentials evoked by stimulation of the lateral column fibers (LC-EPSPs) on lumbar motoneurons in the frog spinal cord. Low concentrations (0.1-0.3 mM) of glutamate, which produced small depolarization, often enhanced EPSP associated with inhibition of a paired pulse facilitation and increased occurrence of spontaneous EPSPs. With 1 mM glutamate, transient enhancement of EPSP was seen in some cells during the early phase or prior to large depolarization, even when input conductance was increased. Transient or sustained enhancement of EPSP was occasionally seen with N-methyl-D-aspartate, kainate and quisqualate, but not with L-2-amino-4-phosphonobutyrate. The results suggest that glutamate enhanced release of excitatory transmitters at low concentrations that apparently did not affect the postsynaptic membrane.

Glutamate-induced inhibition of paired pulse facilitation of monosynaptic excitatory post-synaptic potentials in frog spinal motoneurons

To evaluate actions of glutamate on excitatory synaptic transmission in the central nervous system, we examined glutamate-induced changes in the paired pulse facilitation of monosynaptic excitatory post-synaptic potentials evoked by stimulation of the lateral column fibers (LC-EPSPs) on lumbar motoneurons in the frog spinal cord. Glutamate (1 mM) depolarized motoneurons both in the presence and absence of Mg2+. In most cells perfused with Mg(2+)-free or high Ca(2+)-Mg2+ solutions, the glutamate potential was accompanied by a reduction in peak amplitude of EPSPs, although the degree of change varied with the cells. Glutamate enhanced the EPSP amplitude in a few cells with Mg(2+)-free and high Ca(2+)-Mg2+ solutions, and in most cells with high Mg2+ medium. In 3/5 cells tested, the paired pulse facilitation of EPSPs was reduced by glutamate when the EPSP amplitude either increased or decreased. NMDA (50 microM), kainate (50-100 microM), quisqualate (5-50 microM) and L-2-amino-4-phosphonobutyrate (L-AP4, 1 mM) also decreased the facilitation in about half of the cells tested. The glutamate-induced decrease in the facilitation was observed in both the presence and absence of Mg2+ and was not affected by the concomitant application of glutamate and antagonists for non-NMDA or NMDA receptors, such as 6-cyano-7-nitro-quinoxalinediones (CNQX, 60 microM) or 2-amino-5-phosphonovalerate (APV, 250 microM). Glutamate reduced the facilitation of excitatory post-synaptic currents (EPSCs) recorded at a constant membrane potential under voltage clamp, when the EPSC amplitude either increased or decreased and when the input conductance either increased or decreased.(ABSTRACT TRUNCATED AT 250 WORDS)

Calcium-dependent dynamic changes in the subcellular distribution of calmodulin in frog spinal cells

Calcium-dependent changes in the subcellular distribution of calmodulin (CaM) were investigated using isolated intraarterially perfused frog spinal cords. Perfusion with quin2-tetraacetoxymethyl ester (Q2-AM), an intracellular Ca2+-chelator, increased soluble CaM, measured by radioimmunoassay (RIA), with a concomitant decrease in particulate CaM. By contrast, in synaptosomes, Q2-AM increased soluble CaM and total CaM but not particulate CaM. These results suggest that intracellular Ca2+ controls the binding of CaM to membranes in spinal cells.

Excitatory postsynaptic currents in response to different synaptic inputs of frog spinal motoneurons

Excitatory postsynaptic currents (EPSCs) evoked by the primary afferents (dorsal root; DR) and the descending lateral column (LC) fibers were studied in frog spinal motoneurons under voltage clamp with two separate electrodes. The average rise time and half-width of the EPSCs were shorter for LC-EPSCs than for DR-EPSCs, though the values of the parameters for LC- and DR-EPSCs were distributed within a similar range. The relation between the amplitudes of the EPSP and EPSC was almost linear. The amount of current required to generate a 1 mV increment in the EPSP was 5.0 +/- 2.3 nA for the DR-EPSC and 3.8 +/- 1.2 nA for the LC-EPSC. The decay time was shortened by hyperpolarization and prolonged by depolarization in DR- and LC-EPSCs and spontaneous EPSCs. The reversal potential ranged from -30 to -5 mV and was almost identical for DR- and LC-EPSCs and spontaneous EPSCs in individual motoneurons. The current-voltage relation was linear from -100 to +50 mV for these EPSCs. Spontaneous EPSCs became more prominent and frequent during a large hyperpolarization or a large depolarization. These results suggest that the ionic mechanisms underlying EPSC are similar for the functionally different excitatory synapses located on motoneurons.

Permeability of endoneurial capillaries to K, Na and Cl and its relation to peripheral nerve excitability

The permeability coefficient-surface area products (PA) of frog sciatic nerve endoneurial capillaries to K, Na and Cl were measured with an in situ perfusion technique and found to be 40.3, 24.6 and 32.8 X 10(-5) ml . g-1 . s-1, respectively. PAs to [14C]sucrose and 42K, when measured simultaneously, and their ratio were independent of perfusate K concentration (0.1-10.0 mM). Simultaneous measurements with 36Cl and 42K indicated that the Cl/K permeability ratio was significantly smaller than the mobility ratio of these two ions in free solution. On the other hand, comparable experiments with 22Na and 42K revealed that the K/Na permeability ratio was not significantly different from its respective mobility ratio. Thus, these results provide no evidence of facilitated transport of K by endoneurial capillaries, and suggest that K, Na and Cl traverse the endoneurial capillary wall by a paracellular route which is weakly selective for cations. The minimum extracellular K concentration (Ke) capable of producing a depolarization conduction block in frog sciatic nerve was between 12.5 and 15.0 mM. When the vasculature of this nerve was perfused with a hyperkalaemic (20.0 mM) Ringer solution, a conduction block developed in 7.9 min. Comparison of this time with the theoretically predicted rate of change of endoneurial Ke (induced by a comparable change of intravascular K concentration) indicated that an increase of endoneurial Ke is transmitted directly to the paranodal spaces of nerve fibres so as to immediately influence axonal excitability.(ABSTRACT TRUNCATED AT 250 WORDS)

In vitro studies of the effects of naloxone on the root potentials in the frog spinal cord: enkephalin-like effect on the recurrent presynaptic inhibition

Specific binding of [3H]naloxone was demonstrated in the frog spinal cord. In isolated and perfused frog spinal cord, naloxone increased the spontaneous discharges of the ventral root. Naloxone decreased the ventral root-dorsal root potential (VR-DRP) in a dose-dependent manner, and inhibited presynaptic inhibition of the ventral root reflex. Methionine-enkephalin also decreased the VR-DRP, and naloxone partially antagonized this effect. These results suggest the existence of enkephalinergic control of spinal motor activities and that naloxone has a partial agonistic effect in the frog spinal cord.

Descending and segmental spinal pathways differently regulate contractions of antagonistic muscles of frogs in vitro

A comparison of fibres descending through the ventral column and segmental afferent fibres was carried out using an isolated frog spinal cord-nerve-muscle preparation with a pair of antagonistic muscles. The m. tibialis anterior (TIB) was contracted with stimulation of the ventral column much stronger than with that of the dorsal root (DR). Contraction of the m. gastrocnemius (GAS) was selectively induced with DR stimulation. These results suggest that the descending fibres and segmental afferent fibres preferentially regulate contractions of the flexor (the TIB) and the extensor (the GAS), respectively. Effects of alpha-aminoadipate, methysergide and LSD were also examined.

Enkephalin but not morphine modulates the motor activity in the frog spinal cord in vitro

In the isolated frog spinal cord, methionine-enkephalin (ME, up to 3 X 10(-5) M) hyperpolarized the resting ventral and dorsal root potentials. These hyperpolarizations remained even under Ca2+-free conditions. ME depressed the fast component of the electrically stimulated spinal reflex and enlarged the following depolarizing component. Morphine (10(-4) M) had no apparent ME-like effects. ME may directly and indirectly affect the motoneuron and modulate the spinal motor activity in the frog spinal cord.

The action of taurine on the response to glutamate in the motoneuron of the isolated frog spinal cord

Using the sucrose gap method, the effect of taurine on the response to glutamate in the ventral root of the isolated frog spinal cord was investigated. The depolarization induced by glutamate was reduced by taurine and the inhibitory action of taurine was antagonized by strychnine, but not by picrotoxin or bicuculline. This action of taurine was also unaffected by tetraethylammonium, 4-aminopyridine and Ringer deficient in sodium ions, but was affected by chloride-free Ringer. Potassium-free Ringer abolished the effect of taurine on the amplitude of the response to glutamate, but not on the rising phase of the depolarization induced by glutamate. Taurine also abolished the after-hyperpolarization induced by glutamate and this was reduced by ouabain or lithium ions. These findings suggest that taurine acts on a glycine receptor to inhibit the response to glutamate, that the action of taurine partly depends on chloride ions, and that taurine inhibits the sodium pump.

Pharmacological activation of locomotor patterns in larval and adult frog spinal cords

The effects of amino acids, catecholamines, and their agonists shown to elicit locomotor activity in several vertebrate species were examined in spinal animals and isolated nervous systems of developing tadpoles (Rana catesbiana) and adult frogs (R. catesbiana and pipiens). Elicited activity was correlated in spinal animals by video and electromyographic analysis, and in in vitro spinal cords by recordings of tail and hindlimb motor activity. Of the agents tested, only N-methyl-DL-aspartate (NMA), an amino acid agonist, was effective in eliciting motor activity in spinal animals. In isolated nervous systems, both NMA and D-glutamate added to the bath activated locomotor activity. NMA injected i.p. into tadpoles with high spinal cord transections elicited coordinated swimming motor activity in axial and hindlimb muscles that was roughly typical for the stage of development of the animal. In late stage tadpoles (st. XX), NMA also elicited wiping and alternating or synchronous (i.e. kicking or jumping) hindlimb movements. Addition of NMA or glutamate to a bath containing an in vitro tadpole spinal cord preparation elicited ventral root motor activity characteristic of swimming, but without a rostrocaudal phase lag. Rhythmic activity thought to underlie stepping and kicking was seen in lateral ventral rootlets innervating the hindlimbs. In adult frogs with high spinal cord transections, injection of NMA elicited a general sequence of spontaneous hindlimb motor functions: reflex wiping, stepping, and kicking or jumping. Isolated frog spinal cords were not responsive to bath applied NMA, under the present conditions. The activation by amino acids or their agonists of different motor functions in both larval and adult frogs, as well as in higher and lower vertebrates, suggests a general significance of amino acid-activated receptors in the neural networks controlling locomotor function.

Properties of the depolarization induced by TRH in the isolated frog spinal cord

We observed the excitatory effects of thyrotropin-releasing hormone (TRH) on isolated, intraarterially perfused spinal cords of frogs. TRH (10(-7)-10(-3) M) produced a transient depolarization and potentiated the spontaneous activities in both the ventral and dorsal roots. The TRH effects were related to both direct and indirect actions, and Na+ deficiency attenuated the direct actions. Serotonin was the only neurotransmitter candidate with which TRH exhibited an interaction. Iproniazid potentiated the TRH effects, in normal Ringer's solution. These results indicate that the TRH depolarization due to direct actions is Na+ dependent, and that indirect actions involve an interaction with a monoaminergic pathway.

The actions of serotonin on frog primary afferent terminals and cell bodies

The actions of serotonin (5-HT) were studied in the isolated frog spinal cord and dorsal root ganglion preparations. In the spinal cord, 5-HT increased the spontaneous activity recorded from dorsal roots, facilitated evoked spinal reflexes and produced fast and slow primary afferent depolarization (PAD). A direct action of 5-HT on primary afferent terminals is likely since 5-HT induced PAD remained in the presence of 1 microM tetrodotoxin and 2 mM Mn2+. The direct action of 5-HT on primary afferent terminals was blocked by methysergide and attenuated by concentrations of Mn2+ in excess of that required to block transmitter release. Cell bodies of the dorsal root ganglion were also depolarized by 5-HT. A slow hyperpolarization occasionally followed the initial depolarization. The depolarizing action of 5-HT in the dorsal root ganglion was also attenuated by treatment with Mn2+. It is concluded that 5-HT acts directly on frog primary afferents and that this influence may involve a calcium sensitive process. The dorsal root ganglion response to 5-HT appears to be a suitable model of the afferent terminal response.

Spinal-cord concussion in frogs. A study of reflex changes

A reliable experimental model of the spinal frog, employing the flexor withdrawal reflex to a noxious stimulus, has been used to study the response to single and repeated concussing blows over the spinal column. It is evident that caudally placed blows depress the reflex response, whereas more cephalad blows facilitate the response. The results of studies using repeated concussing blows support the concept that neuronal units may completely lose their function without suffering permanent structural damage.

Supersensitivity of the GABA receptor in the frog spinal cord, as induced by kainic acid

In the isolated frog spinal cord perfused with kainic acid (KA, 5 X 10(-4) M) containing Ringer's solution, within 2 hr there were increases in the amplitude of the dorsal root depolarization, as induced by the GABA-agonists. KA perfusion produced increases in the specific binding of [3H]muscimol to crude synaptic membranes and incubation with KA for 3 hr did not increase [3H]muscimol binding. [3H]GABA was released from KA-treated spinal cord slices in the presence of high K+. KA-induced supersensitivity of the dorsal root to GABA may relate to direct actions on primary afferent terminals and not to denervation of GABAergic neurons.

Sites and mechanisms of action of lidocaine upon the isolated spinal cord of the frog

The sites of action of lidocaine on the responses evoked by stimulation of lateral column (LC) and dorsal root (DR) were studied in the isolated, intra-arterially perfused spinal cord of the bullfrog. When the ventral root volley produced by stimulation was abolished by lidocaine, the presynaptic focal potential was almost unchanged. Intracellular recordings from motoneurons clearly demonstrated a marked reduction in amplitude of the EPSPs before the block of conduction of presynaptic fibers and the block of invasion of the neuron soma by antidromic spike potential. At low concentrations of lidocaine, the EPSPs elicited by LC stimulation produced shortening in time to peak, slowing in the decay time, decrease in amplitude and smaller changes in the later EPSPs of a train than the earlier ones. From the observations, it was concluded that the low concentrations of lidocaine affected primarily synaptic transmission in the spinal cord. The possible mechanisms of action of lidocaine were discussed.

The role of calcium ion in the L-glutamate-induced depolarization in the frog spinal cord

1. The role of Ca2+ in L-glutamate-induced depolarization was investigated in the isolated frog spinal cord. 2. The size of a depolarization induced by L-glutamate (3 mM) was inversely related to the extracellular Ca2+ concentration, but was reduced in a Ca2+-free medium containing EGTA (0.3 mM). 3. L-Glutamate caused a marked depolarization in both ventral and dorsal roots, even in a NaCl-deficient medium (Ca2+, 2.0 mM). The size of the depolarization was attenuated by a prolonged or repeated application of L-glutamate. Ca2+ can be replaced by Sr2+ or Mg2+. 4. Concanavalin A (1 microM) prevents the development of desensitization to L-glutamate. 5. Present results suggest that Ca2+ plays the role of a charge carrier for L-glutamate-induced depolarization and of a regulator of modulator for L-glutamate-receptor sensitivity. The roles are exaggerated in NaCl-free medium.

Alterations in spontaneous activity of the isolated frog spinal cord in Calcium-free environment

Spontaneous electrical activity of the isolated frog spinal cord was examined in Ca2+-free environment. Spontaneous discharges from the ventral root altered in four distinguishable steps. The first step was an immediate increase in the rate of spontaneous discharges and the second was a gradual decrease. The third was the occurrence of rhythmical bursts, and the last, the appearance of continuous firing. The rhythmical bursts could be depressed by the addition of metabolic inhibitors (ouabain or dinitrophenol in a concentration of 5 x 10(-5) M) as well as of Ca2+-chelating agents (EDTA or EGTA in a concentration of 10(-3) M). Our results suggest that the occurrence of the rhythmical bursts requires a metabolic pumping process to redistribute Na+ and K+ across the membrane and a small amount of Ca2+ for transmitter secretion.

Effects of beta-(p-chlorophenyl)-GABA (baclofen) on spinal synaptic activity

In the isolated perfused spinal cord of the bullfrog, baclofen caused a reduction in the rate of spontaneous discharges in the ventral root at lower concentrations than GABA. The inhibitory effect of baclofen was fully present in a chloride-free medium, whereas that of GABA was markedly reduced. In contrast to GABA, which depolarized the dorsal root, baclofen produced a hyperpolarization in the dorsal root. Moreover, baclofen produced a hyperpolarization in the ventral roots. In the rat, the development of spinal reflex inhibition by baclofen was slow and the effect was long-lasting. Baclofen decreased dorsal root reflexes, suggesting a decreased excitability of presynaptic fibres. Baclofen produced a more pronounced and faster inhibitory effect on monosynaptic reflexes than on polysynaptic reflexes. In the monoamine depleted rat, the effect of baclofen on both types of reflexes was markedly reduced. It appears that catecholamines are involved in the effects produced by baclofen.

The chloride-dependent depression by GABA in the frog spinal cord

Spontaneous activities from ventral and dorsal roots of the isolated perfused spinal cord of the bullfrog were inhibited by GABA. beta-Alanine showed a strong and glycine a weaker inhibitory effect. The inhibitory effect of GABA was markedly reduced in a chloride-free medium, whereas glycine and beta-alanine still showed an inhibitory effect similar to that seen in normal medium. Employing the sucrose-gap method, a marked depolarization in the dorsal root and a small but obvious hyperpolarization in the ventral root were found by the application of GABA. These results support the view that GABA is one of the transmitters involved in pre- and postsynaptic inhibition of the spinal cord. The postsynaptic hyperpolarizing effect of GABA on motoneurones would be caused directly through increased permeability of the membrane to chloride ion. The depolarizing effect of GABA on primary afferent terminals is discussed in connection with chloride dependency.