Glutamate and synaptic excitation of reticulospinal neurones of lamprey

Brainstem neural mechanisms controlling locomotion with special reference to basal vertebrates

Over the last 60 years, the basic neural circuitry responsible for the supraspinal control of locomotion has progressively been uncovered. Initially, significant progress was made in identifying the different supraspinal structures controlling locomotion in mammals as well as some of the underlying mechanisms. It became clear, however, that the complexity of the mammalian central nervous system (CNS) prevented researchers from characterizing the detailed cellular mechanisms involved and that animal models with a simpler nervous system were needed. Basal vertebrate species such as lampreys, xenopus embryos, and zebrafish became models of choice. More recently, optogenetic approaches have considerably revived interest in mammalian models. The mesencephalic locomotor region (MLR) is an important brainstem region known to control locomotion in all vertebrate species examined to date. It controls locomotion through intermediary cells in the hindbrain, the reticulospinal neurons (RSNs). The MLR comprises populations of cholinergic and glutamatergic neurons and their specific contribution to the control of locomotion is not fully resolved yet. Moreover, the downward projections from the MLR to RSNs is still not fully understood. Reporting on discoveries made in different animal models, this review article focuses on the MLR, its projections to RSNs, and the contribution of these neural elements to the control of locomotion. Excellent and detailed reviews on the brainstem control of locomotion have been recently published with emphasis on mammalian species. The present review article focuses on findings made in basal vertebrates such as the lamprey, to help direct new research in mammals, including humans.

Glutamatergic neuronal populations in the brainstem of the sea lamprey, Petromyzon marinus: an in situ hybridization and immunocytochemical study

Glutamate is the major excitatory neurotransmitter in vertebrates, and glutamatergic cells probably represent a majority of neurons in the brain. Physiological studies have demonstrated a wide presence of excitatory (glutamatergic) neurons in lampreys. The present in situ hybridization study with probes for the lamprey vesicular glutamate transporter (VGLUT) provides an anatomical basis for the general distribution and precise localization of glutamatergic neurons in the sea lamprey brainstem. Most glutamatergic neurons were found within the periventricular gray layer throughout the brainstem, with the following regions being of particular interest: the optic tectum, torus semicircularis, isthmus, dorsal and medial nuclei of the octavolateral area, dorsal column nucleus, solitary tract nucleus, motoneurons, and reticular formation. The reticular population revealed a high degree of cellular heterogeneity including small, medium-sized, large, and giant glutamatergic neurons. We also combined glutamate immunohistochemistry with neuronal tract-tracing methods or γ-aminobutyric acid (GABA) immunohistochemistry to better characterize the glutamatergic populations. Injection of Neurobiotin into the spinal cord revealed that retrogradely labeled small and medium-sized cells of some reticulospinal-projecting groups were often glutamate-immunoreactive, mostly in the hindbrain. In contrast, the large and giant glutamatergic reticulospinal perikarya mostly lacked glutamate immunoreactivity. These results indicate that glutamate immunoreactivity did not reveal the entire set of glutamatergic populations. Some spinal-projecting octaval populations lacked both VGLUT and glutamate. As regards GABA and glutamate, their distribution was largely complementary, but colocalization of glutamate and GABA was observed in some small neurons, suggesting that glutamate immunohistochemistry might also detect non-glutamatergic cells or neurons that co-release both GABA and glutamate.

Glutamatergic neuronal populations in the forebrain of the sea lamprey, Petromyzon marinus: an in situ hybridization and immunocytochemical study

Despite the importance of glutamate as a major excitatory neurotransmitter in the brain, the distribution of glutamatergic populations in the brain of most vertebrates is still unknown. Here, we studied for the first time the distribution of glutamatergic neurons in the forebrain of the sea lamprey (Petromyzon marinus), belonging to the most ancient group of vertebrates (agnathans). For this, we used in situ hybridization with probes for a lamprey vesicular glutamate transporter (VGLUT) in larvae and immunofluorescence with antiglutamate antibodies in both larvae and adults. We also compared glutamate and γ-aminobutyric acid (GABA) immunoreactivities in sections using double-immunofluorescence methods. VGLUT-expressing neurons were observed in the olfactory bulb, pallium, septum, subhippocampal lobe, preoptic region, thalamic eminence, prethalamus, thalamus, epithalamus, pretectum, hypothalamus, posterior tubercle, and nucleus of the medial longitudinal fascicle. Comparison of VGLUT signal and glutamate immunoreactivity in larval forebrain revealed a consistent distribution of positive cells, which were numerous in most regions. Glutamate-immunoreactive cell populations were also found in similar regions of the adult forebrain. These include mitral-like cells of the olfactory bulbs and abundant cells in the lateral pallium, septum, and various diencephalic regions, mainly in the prethalamus, thalamus, habenula, pineal complex, and pretectum. Only a small portion of the glutamate-immunoreactive cells showed colocalization with GABA, which was observed mainly in the olfactory bulb, telencephalon, hypothalamus, ventral thalamus, and pretectum. Comparison with glutamatergic cells observed in rodent forebrains suggests that the regional distribution of glutamatergic cells does not differ greatly in lampreys and mammals.

Glutamate regulates neurite outgrowth of cultured descending brain neurons from larval lamprey

In larval lamprey, descending brain neurons, which regenerate their axons following spinal cord injury, were isolated and examined in cell culture to identify some of the factors that regulate neurite outgrowth. Focal application of 5 mM or 25 mM L-glutamate to single growth cones inhibited outgrowth of the treated neurite, but other neurites from the same neuron were not inhibited, an effect that has not been well studied for neurons in other systems. Glutamate-induced inhibition of neurite outgrowth was abolished by 10 mM kynurenic acid. Application of high potassium media to growth cones inhibited neurite outgrowth, an effect that was blocked by 2 mM cobalt or 100 microM cadmium, suggesting that calcium influx via voltage-gated channels contributes to glutamate-induced regulation of neurite outgrowth. Application of glutamate to growth cones in the presence of 2 microM omega-conotoxin MVIIC (CTX) still inhibited neurite outgrowth, while CTX blocked high potassium-induced inhibition of neurite outgrowth. Thus, CTX blocked virtually all of the calcium influx resulting from depolarization. To our knowledge, this is the first direct demonstration that calcium influx via ligand-gated ion channels can contribute to regulation of neurite outgrowth. Finally, focal application of glutamate to the cell bodies of descending brain neurons inhibited outgrowth of multiple neurites from the same neuron, and this is the first demonstration that multiple neurites can be regulated in this fashion. Signaling mechanisms involving intracellular calcium, similar to those shown here, may be important for regulating axonal regeneration following spinal cord injury in the lamprey.

Ca2+-independent, but voltage- and activity-dependent regulation of the NMDA receptor outward K+ current in mouse cortical neurons

To test the novel hypothesis that the K+ efflux mediated by NMDA receptors might be regulated differently than the influx of Ca2+ and Na+ through the same receptor channels, NMDA receptor whole-cell currents carried concurrently or individually by Ca2+, Na+ and K+ were analysed in cultured mouse cortical neurons. In contrast to the NMDA inward current carried by Ca2+ and Na+, the NMDA receptor outward K+ current or NMDA-K current, recorded either in the presence or absence of extracellular Ca2+ and Na+, and at different or the same membrane potentials, showed much less sensitivity to alterations in intracellular Ca2+ concentration and underwent little rundown. In line with a selective regulation of the NMDA receptor K+ permeability, the ratio of the NMDA inward/outward currents decreased, and the reversal potential of composite NMDA currents recorded in physiological solutions shifted by -8.5 mV after repeated activation of NMDA receptors. Moreover, a depolarizing pre-pulse of a few seconds or a burst of brief depolarizing pulses selectively augmented the subsequent NMDA-K current, but not the NMDA inward current. On the other hand, a hyperpolarizing pre-pulse showed the opposite effect of reducing the NMDA-K current. The voltage- and activity-dependent regulation of the NMDA-K current did not require the existence of extracellular Ca2+ or Ca2+ influx; it was, however, affected by the duration of the pre-pulse and was subject to a time-dependent decay. The burst of excitatory activity revealed a lasting upregulation of the NMDA-K current even 5 s after termination of the pre-pulses. Our data reveal a selective regulation of the NMDA receptor K+ permeability and represent a novel model of voltage- and excitatory activity-dependent plasticity at the receptor level.

Regulation and critical role of potassium homeostasis in apoptosis

Programmed cell death or apoptosis is broadly responsible for the normal homeostatic removal of cells and has been increasingly implicated in mediating pathological cell loss in many disease states. As the molecular mechanisms of apoptosis have been extensively investigated a critical role for ionic homeostasis in apoptosis has been recently endorsed. In contrast to the ionic mechanism of necrosis that involves Ca(2+) influx and intracellular Ca(2+) accumulation, compelling evidence now indicates that excessive K(+) efflux and intracellular K(+) depletion are key early steps in apoptosis. Physiological concentration of intracellular K(+) acts as a repressor of apoptotic effectors. A huge loss of cellular K(+), likely a common event in apoptosis of many cell types, may serve as a disaster signal allowing the execution of the suicide program by activating key events in the apoptotic cascade including caspase cleavage, cytochrome c release, and endonuclease activation. The pro-apoptotic disruption of K(+) homeostasis can be mediated by over-activated K(+) channels or ionotropic glutamate receptor channels, and most likely, accompanied by reduced K(+) uptake due to dysfunction of Na(+), K(+)-ATPase. Recent studies indicate that, in addition to the K(+) channels in the plasma membrane, mitochondrial K(+) channels and K(+) homeostasis also play important roles in apoptosis. Investigations on the K(+) regulation of apoptosis have provided a more comprehensive understanding of the apoptotic mechanism and may afford novel therapeutic strategies for apoptosis-related diseases.

Glutamate receptor-mediated synaptic excitation in axons of the lamprey

1. Spontaneous and evoked synaptic inputs were recorded in vitro in the axons of lamprey reticulospinal neurones. After isolation of the axon from its somata, synaptic inputs were recorded using microelectrode and whole-cell patch clamp recording techniques. 2. Single stimuli applied to the spinal cord elicited Ca(2+)-dependent synaptic potentials with short latencies in reticulospinal axons. These synaptic inputs are capable of summation and generate sufficient depolarization to raise the membrane potential beyond threshold to initiate action potentials. Action potential initiation in the absence of the cell body indicates that these axons show synaptic integration. 3. Both evoked and spontaneous responses comprise at least two components of synaptic drive: a slow component (rise time of 9.6 +/- 2.1 ms) with a reversal potential of -53 +/- 19 mV and a fast component (rise time as fast as 0.85 ms) with a reversal potential of 0.3 +/- 9.1 mV. The responses are Ca2+ dependent, and are blocked by the substitution of Ba2+ for Ca2+ in the saline solution. 4. The slow component of synaptic input was blocked by the gamma-aminobutyric acidA (GABAA) receptor antagonist bicuculline (5 microM). The fast component was blocked by the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor antagonist 6-cyano-7-nitroqinoxaline-2,3-dione (CNQX; 10 microM) in Ringer solution containing physiological concentrations of Mg2+. Following removal of Mg2+ from the superfusate a further excitatory component was identified that was blocked by application of the N-methyl-D-aspartate (NMDA) receptor antagonist 2-amino-5-phosphonopentanoate (AP5; 100 microM). 5. Comparison of the kinetic properties and the voltage sensitivity of the isolated components of evoked and spontaneous synaptic activity indicate that these responses are mediated by similar synaptic inputs. 6. These results suggest that axons and presynaptic terminals receive excitatory and inhibitory ionotropic receptor-mediated inputs. Summation of these inputs is possible indicating that the axons act as sites of synaptic integration similar to the role previously attributed only to neuronal dendrites and somata.

Trigeminal inputs to reticulospinal neurones in lampreys are mediated by excitatory and inhibitory amino acids

Reticulospinal (RS) neurones integrate sensory inputs from several modalities to generate appropriate motor commands for maintaining body orientation and initiation of locomotion in lampreys. As in other vertebrates, trigeminal afferents convey sensory inputs from the head region. The in vitro brainstem/spinal cord preparation of the lamprey was used for characterizing trigeminal inputs to RS neurones as well as the transmitter systems involved. The trigeminal nerve on each side was electrically stimulated and synaptic responses, which consisted of mixed excitation and inhibition, were recorded intracellularly in the middle and posterior rhombencephalic reticular nuclei. The EPSPs were mediated by activation of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA)/kainate receptors. An increase in the late phase of the excitatory response occurred when Mg2+ ions were removed from the Ringer's solution. This effect was antagonized by 2-amino-5-phosphonopentanoate (2-AP5) or reversed by restoring Mg2+ ions to the perfusate suggesting the activation of N-methyl-D-aspartate (NMDA) receptors. IPSPs were mediated by glycine. These findings are similar to those reported for other types of sensory inputs conveyed to RS neurones, where excitatory and inhibitory amino acid transmission is also involved.

Excitatory amino acid-evoked membrane currents and excitatory synaptic transmission in lamprey reticulospinal neurons

The characteristics of excitatory amino acid-evoked currents and of excitatory synaptic events have been examined in lamprey Müller neurons using voltage clamp and current clamp recording techniques. Application of glutamate evoked depolarizations associated with a decrease in input resistance. The reversal potential of the responses was -35 mV. Under voltage clamp conditions, a series of excitatory amino acid agonists evoked inward currents associated with little or no increase in baseline current noise. The order of potency of the excitatory amino acid agonists was quisqualate greater than kainate greater than glutamate greater than aspartate, while N-methyl-D-aspartic acid (NMDA) was inactive. Inward currents evoked by glutamate, as well as by kainate and quisqualate were attenuated reversibly by 1 mM kynurenic acid (KYN). In contrast, glutamate-evoked currents were not affected by 100 microM D(-)-2-amino-5-phosphonovaleric acid (APV), a selective NMDA antagonist. Spontaneously occurring and stimulus-evoked excitatory postsynaptic events were antagonized reversibly by 1 mM KYN. At this concentration, KYN had no effect on membrane potential, input resistance, or excitability of the cells. In contrast, excitatory postsynaptic currents were unaffected by APV. It is concluded that both glutamate responses and excitatory synaptic transmission in lamprey Müller neurons are mediated by non-NMDA-type receptors and that these receptors are associated with ionic channels with a low elementary conductance. The combined pharmacological and biophysical characteristics of these responses are therefore different from those previously reported in other preparations. Spontaneous (but not stimulus-evoked) inhibitory synaptic events in Müller neurons were blocked reversibly by 1 mM KYN but not by 100 microM APV, suggesting that excitation of interneurons inhibitory to Müller cells was also mediated by non-NMDA receptors.

Permeation and block of N-methyl-D-aspartic acid receptor channels by divalent cations in mouse cultured central neurones

1. Spinal cord and hippocampal neurones in cell culture were voltage clamped using the tight-seal, whole-cell recording technique. The concentration of sodium and a series of divalent cations in the extracellular media was varied to study permeation through excitatory amino acid receptor channels activated by the selective agonists N-methyl-D-aspartic acid (NMDA), kainic acid and quisqualic acid. 2. On raising the extracellular calcium concentration, with [Na+]o held constant at 105 mM, the reversal potential of responses to NMDA shifted in the depolarizing direction. This shift was adequately described by the extended constant-field equation over the range 0.3-50 mM-calcium. Using ionic activity coefficients we calculate a value of PCa/PNa = 10.6. Under the same experimental conditions the reversal potential of responses to kainic and quisqualic acids was much less affected by raising the calcium concentration, such that PCa/PNa = 0.15. A depolarizing shift of the NMDA reversal potential was also recorded during application of 20 mM-barium, strontium or manganese, suggesting permeation of these ions. The permeability sequence was Ca2+ greater than Ba2+ greater than Sr2+ much greater than Mn2+. No depolarizing shift of the NMDA reversal potential occurred during application of 20 mM-cobalt, magnesium or nickel. 3. In experiments in which the extracellular Na+ concentration was varied the extended constant-field equation was adequate in predicting shifts of the NMDA reversal potential recorded on varying [Na+]o over the range 50-150 mM, but failed to accurately predict the reversal potential of responses to NMDA with 10 mM-[Ca2+]o and only 10 or 20 mM-[Na+]o. These results imply an apparent increase in PCa/PNa on lowering [Na+]o and may result from interaction of permeant ions within the channel. 4. Barium and to a lesser extent calcium, but not strontium (all 20 mM), reduced the slope conductance of responses to NMDA recorded within +/- 15 mV of the reversal potential; over this limited range of membrane potential the current-voltage relationship remained linear in the presence of each of these ions. In contrast manganese produced a strong, voltage-dependent block of responses to NMDA, similar to that produced by magnesium, such that even close to the reversal potential the NMDA current-voltage relationship was highly non-linear. Thus manganese both permeates and blocks the NMDA receptor channel. 5. Raising the extracellular calcium concentration, from 0.1 to 5 mM, had two effects on the conductance mechanism activated by NMDA.(ABSTRACT TRUNCATED AT 400 WORDS)

The action of excitatory amino acids on chick spinal cord neurones in culture

1. Membrane currents evoked by N-methyl-D-aspartate (NMDA), L-aspartate, L-glutamate, quisqualate and kainate were studied in cultured neurones from the embryonic chick spinal cord by the patch-clamp technique and by employing a quasi-step microperfusion technique. 2. Application of NMDA, aspartate, glutamate and quisqualate induced currents which exhibited an initial peak which declined to a plateau level with a time constant of 2 s and then remained constant or slowly decreased. The discontinuation of the application was followed by an after-current. The individual components of the responses were insensitive to TTX (2 X 10(-6) M) and were present in neurones which did not exhibit any sign of synaptic activity. The responses induced by kainate were monophasic and declined slowly during long-lasting application. 3. The responses induced by NMDA, aspartate and glutamate were voltage dependent, while those induced by kainate were linear between -80 and +80 mV. The equilibrium potential for all components of the responses to all excitatory amino acids was close to zero. 4. From dose-response curves the half-maximum effective dose (ED50) for glutamate and kainate was 3 X 10(-5) and 2 X 10(-4) M respectively. The Hill coefficients for the glutamate and the kainate were calculated to be 1.8 +/- 0.1 (n = 4) and 1.9 +/- 0.5 (n = 4) respectively. Thus two molecules may be interacting with each of the receptor-activated ion channels. 5. Interaction between kainate and quisqualate or kainate and NMDA was studied at both negative and positive holding potentials. No summation of the responses was found when kainate at concentrations close to those required for evoking the maximum response was applied simultaneously with quisqualate or NMDA. On the contrary, a diminution of the membrane currents was observed. A marked decrease in membrane currents was also observed when glutamate (10(-4) M) was applied simultaneously with aspartate (10(-4) M). 6. Glutamate-activated single-channel currents were recorded in the cell-attached configuration with electrodes filled with glutamate (20 microM) in five neurones and a conductance approximately 50 pS was found. 7. It is suggested that differences in the potency of the different excitatory amino acids as open-channel blockers may be one of the mechanisms which contribute to the diversity in the action of excitatory amino acids and that at least some of the effects of NMDA, aspartate, glutamate, quisqualate and kainate may be mediated by a common receptor-channel complex.

Electrophysiological and pharmacological actions of N-acetylaspartylglutamate intracellularly studied in cultured chick cerebellar neurons

The electrophysiological and pharmacological actions of N-acetylaspartylglutamate (NAAG) in cultured chick cerebellar neurons were intracellularly investigated in comparison with L-aspartate (ASP) and L-glutamate (GLU). Iontophoretically applied NAAG dose-dependently induced depolarizations associated with increases in spike discharge and changes in membrane conductance. Relative excitatory potencies seemed to be GLU greater than ASP greater than or equal to NAAG. The voltage-dependent increase in input resistance observable in the presence of Mg ions was most notable for ASP, moderate for NAAG and least for GLU. The reversal potential of NAAG-induced depolarization was at about 0 mV and similar to that for ASP or GLU, indicating primary concern of Na+/K+-conductances to the NAAG action. Mg ions depressed the actions of ASP and NAAG more strongly than the GLU action. 2-Amino-5-phosphonovalerate (APV) and D-alpha-aminoadipate antagonized the actions of ASP and NAAG more effectively than the GLU action. 2-Amino-4-phosphonobutyrate (APB) and glutamic acid diethylester showed rather non-selective antagonisms to NAAG, ASP and GLU. These results suggest that NAAG is excitatory to cultured chick cerebellar neurons and functionally resembles ASP or is intermediate between ASP and GLU, and may also support the suggested candidacy of NAAG for a neurotransmitter in the CNS.

Pharmacological aspects of excitatory synaptic transmission to second-order vestibular neurons in the frog

Synaptic excitation of second-order vestibular neurons is mediated by two principal afferents: vestibular afferents projecting into the brain via the VIIIth cranial nerve and commissural afferents from the contralateral vestibular nuclear complex. The shape of the excitatory postsynaptic potentials (EPSPs) generated by selectively activating these two inputs differs qualitatively, such that ipsilateral VIIIth nerve afferents generate a faster-rising EPSP than do the commissural afferents. We have investigated the synaptic pharmacology of these two inputs in the isolated, intact medulla of the frog in order to determine the nature of the transmitter substances released by the afferents and the nature of the subsynaptic receptors with which these transmitters interact. Electrical stimulation of the ipsilateral VIIIth cranial nerve evokes in the region of the vestibular nuclear complex a field potential that exhibits a presynaptic (afferent volley) and a postsynaptic (slow negativity) component. Bath application of glutamate receptor antagonists, such as kynurenic acid (KENYA), blocks the postsynaptic component of this field potential in a dose-dependent manner, without affecting the presynaptic volley, suggesting that the VIIIth nerve afferent releases glutamate and/or similar substances as its neurotransmitter. A comparison of the actions of various glutamate receptor antagonists to block this postsynaptic negativity gives a rank order of effectiveness such that KENYA greater than gamma-D-glutamylglycine (gamma DGG) = gamma-D-glutamylaminomethylsulfonic acid (GAMS) greater than gamma-D-glutamyltaurine (gamma DGT) much greater than gamma-D-glutamylaminomethylphosphonic acid (GAMP) greater than D-2-amino-5-phosphonovaleric acid (D-APV) greater than D,L-APV greater than D-2-amino-7-phosphonoheptanoic acid (APH). This rank order of effectiveness suggests that the VIIIth nerve transmitter activates second-order neurons through kainate (KA)/quisqualate (QUIS) synaptic receptors. Intracellular studies support these conclusions. Chemically mediated EPSPs evoked from ipsilateral VIIIth nerve stimulation are completely blocked by high concentrations of KENYA (greater than or equal to 1 mM). Occasionally an extremely short-latency, probably electrically mediated, component to these EPSPs persists in the presence of KENYA. The slower-rising EPSPs evoked from contralateral VIIIth nerve or contralateral vestibular nuclear complex stimulation are also completely blocked by KENYA, suggesting that the transmitter released by the commissural afferents is also glutamate and/or related compounds.(ABSTRACT TRUNCATED AT 400 WORDS)

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.

Effects of injectable anaesthetics on responses to L-glutamate and on spontaneous synaptic activity in lamprey reticulo-spinal neurones

Intracellular recordings were made from reticulo-spinal cells in the medulla of lamprey ammocoetes; potential changes in response to iontophoretically applied L-glutamate were measured before, during and after the preparation was superfused with anaesthetic solutions. Of the anaesthetics pentobarbitone, ketamine, alphaxalone/alphadolone (Saffan) and metomidate, only pentobarbitone (greater than 10 microM) had a consistent dose-related depressant effect on glutamate responses. Spontaneous excitatory postsynaptic potentials (e.p.s.ps) and inhibitory postsynaptic potentials (i.p.s.ps) were diminished in frequency by high concentrations (1 mM) of all anaesthetics. Anaesthetic concentrations of all drugs also reduced i.p.s.ps; for e.p.s.ps this was true of pentobarbitone (100 microM) immediately, and of ketamine (370 microM) and alphaxalone (10-30 microM) after a transitory increase in activity. Consideration of the results in the light of previous observations on inhibitory responses suggests a basis for some of the excitatory side effects of these compounds, assuming that the equivalent mammalian cells are similarly affected.

The reversal potential of excitatory amino acid action on granule cells of the rat dentate gyrus

The responses of granule cells to glutamate, aspartate, N-methyl-D-aspartate (NMDA), quisqualate and kainate applied by ionophoresis on to their dendrites in the middle molecular layer of the dentate gyrus were studied with intracellular electrodes using an in vitro hippocampal slice preparation. On passive depolarization 75% of the granule cells displayed anomalous rectification, which persisted in the presence of TTX and TEA but was eliminated by Co2+ or the intracellular injection of Cs+. Short ionophoretic applications of all the excitatory amino acids evoked dose-dependent depolarizations that were highly localized: movement of the ionophoretic electrode by as little as 10 microns could substantially change the size of the response. The depolarizations evoked by glutamate, asparatate, quisqualate and kainate were unaffected by TTX and Co2+. The depolarization evoked by NMDA was unaffected by TTX but markedly reduced by Co2+. Following intracellular injection of Cs+, neurones could be depolarized to +30 mV and the depolarizations produced by glutamate, quisqualate, NMDA and kainate reversed. The reversal potentials (E) were Eglutamate: -5.6 +/- 0.4 mV; ENMDA: 1.8 +/- 1.9 mV; Equisqualate: -3.9 +/- 1.9 mV; Ekainate: -4.6 +/- 2.0 mV. The excitatory post-synaptic potential (e.p.s.p.) evoked by stimulation of the medial perforant path could also be reversed and Ee.p.s.p. was -5.5 +/- 1.1 mV. The 6 mV difference between ENMDA and the equilibrium potential for the other exogenously applied excitatory amino acids and the statistically significant difference between ENMDA and Ee.p.s.p. (P less than 0.005; d.f.: 7) is consistent with our earlier hypothesis that both the transmitter released by the medial perforant path and exogenously applied glutamate are unlikely to interact with NMDA receptors.

Differential sensitivity of spinal neurones to amino acids: an intracellular study on the frog spinal cord

Intracellular recordings from in vitro neurones of the frog spinal cord slice preparation were performed in order to examine the mechanism of action of gamma-aminobutyrate and glutamate on two distinct neuronal populations in the same region of the central nervous system. Amino acids were superfused at fast rate and low temperature (7 degrees C) to reduce their uptake process. On interneurones, the inhibitory action of gamma-aminobutyrate was characterized by a large input conductance increase while on motoneurones the conductance change was much smaller. Glutamate excited interneurones which greatly increased their input conductance and showed burst firing; motoneurones were also excited by glutamate but usually did not fire repeatedly nor showed large conductance changes. In spite of these differences the amplitude of depolarization in the presence of the same concentration of glutamate was similar for motoneurones and interneurones. It is suggested that amino acids (particularly glutamate) may act through different membrane mechanisms on two neuronal populations in the same region of the spinal cord.

Serotonin-induced depolarization of rat facial motoneurons in vivo: comparison with amino acid transmitters

Intracellular recordings were obtained from facial motoneurons in anesthetized rats. The effects of iontophoretically applied serotonin were compared to those of the excitatory amino acids glutamate and DL-homocysteic acid (DLH), and the inhibitory amino acids, glycine, GABA and muscimol, under various conditions of membrane polarization and intracellular chloride concentration. Iontophortically applied serotonin caused a depolarization of facial motoneurons which was accompanied by increased input resistance and increased neuronal excitability. Experiments comparing the response to serotonin with those of glycine, GABA, and muscimol demonstrated that the serotonin effect does not involve changes in membrane conductance to chloride. Comparisons of serotonin with glutamate and DLH at varying levels of membrane hyperpolarization indicated that the serotonin-induced depolarization is not caused by increased conductance to sodium or calcium, and differs in its underlying ionic mechanism from depolarizations induced by glutamate and DLH. Results were consistent with the hypothesis that serotonin causes depolarization, increased input resistance, and increased excitability in rat facial motoneurons by decreasing resting membrane conductance to potassium ions. Such changes in motoneurons in the brain stem and spinal cord probably account for some of the physiological and behavioral effects observed during pharmacological activation of serotonin receptors.

Effect of glutamate, aspartate and related derivatives on cerebellar purkinje cell dendrites in the rat: an in vitro study

1. The responses of Purkinje cells to short duration (pulse) ionophoretic applications of L-aspartate (L-asp), L-glutamate (L-glu), N-methyl DL-aspartate (NMDLA) and quisqualic acid in their dendritic fields were studied in vitro on sagittal slices of lobules IX and X of the adult rat cerebellum.2. Pulse application of L-asp or L-glu evoked transient and dose-dependent increases in the firing rate of the simple spikes recorded extracellularly as single units. When the ionophoretic electrode was positioned in the dendritic field of the Purkinje cells, the lowest thresholds for L-glu and L-asp mediated excitations of the cells were as low as 25 and 35 pC respectively, with a latency for maximal responses as brief as 7 ms.3. In intracellular recordings these excitatory responses consisted of depolarizations of up to 18 mV in amplitude and with depolarizing slopes up to 0.52 mV/ms. They were generally unaccompanied by changes in cell input resistance in contrast to the marked decrease which occurred in response to steady applications of large doses of L-asp and L-glu.4. The spatial distribution of the excitatory sites confirmed that the dendritic sensitivity to L-glu was greater than that of the soma and showed that the same was true for L-asp. In 34% of cells the sensitivity for L-asp declined markedly in the upper region of the molecular layer, whereas it remained high for L-glu; no such differential sensitivity was detected in the remaining 66% of cells.5. Inhibitory responses, antagonized by 10(-5) M-bicuculline in the bath, were also induced in Purkinje cells by L-glu and L-asp when the ionophoretic electrode was withdrawn from the excitatory sites by as little as 8 mum and up to 40 mum upward or downward along the track of parallel fibres or positioned as far as 250 mum laterally.6. Whenever it was applied in the molecular layer, the pulse application of NMDLA elicited no excitatory response in Purkinje cells recorded extra or intracellularly. However, slow depolarizations accompanied by a slight increase in cell input resistance were obtained with steady applications of 20-50 nA of the drug for 20-30 s.7. In contrast, pulse application of quisqualic acid appeared to have the same type of fast excitatory effect on Purkinje cells as L-asp and L-glu, but its potency was greater and its action more prolonged. Furthermore, its steady application led to an abrupt and marked decrease in cell membrane resistance.8. The excitatory effects of L-asp, L-glu and quisqualic acid were antagonized by L-glutamic acid diethyl ester more consistently than by D-alpha-aminoadipate, suggesting together with previous observations that L-asp and L-glu act on Purkinje cells via quisqualic acid rather than via NMDLA receptors.

Selective potentiation of retinal horizontal cell responses to L-glutamate by D-aspartate

1. L-Glutamate and L-aspartate depolarize type H1 horizontal cells in the isolated retina of goldfish, but only at millimolar concentrations. 2. When applied in the presence of D-aspartate, L-glutamate depolarizes H1 cells at concentrations nearly 15-fold lower than when it is applied alone. The effects of L-aspartate were not potentiated by either D-aspartate or D-glutamate. 3. Since D-aspartate seems also to enhance the effect of the transmitter released by cone photoreceptors, these results are consistent with the possibility that L-glutamate is a neurotransmitter of cones.

Multiple reversal potentials for responses to L-glutamic acid

Reversal potentials for L-glutamic and kainic acid were determined from foetal mouse neurones, grown dissociated in culture, and originating either from the brain or spinal cord. Amino acids were applied at known concentrations by pressure microperfusion and responses recorded using conventional intracellular techniques. Altering membranes potential by injecting current through the recording electrode permitted direct (not extrapolated) observation of reversal potentials. Values of reversal potentials differed from previous reports in culture but were still well below those predicted solely from an increase in sodium conductance. Furthermore, with some neurones it was possible to demonstrate multiple phases of response, each phase differing in time course and possessing a separate reversal potential. One reversal potential indicated the participation of potassium conductance in the response.

Intracellularly-recorded effects of glutamate and aspartate on neurones in the guinea-pig olfactory cortex slice

The effects of bath-applied glutamate, aspartate (and some related amino acids) on neurones of the guinea pig olfactory cortex slice were recorded intracellularly. Neurones were activated either by intracellularly-applied current or orthodromically by stimulating the lateral olfactory tract. In response to orthodromic stimuli several neurones displayed a late hyperpolarizing potential (LHP) after the usual sequence of EPSP, spike and IPSP. Glutamate and aspartate evoked 3 types of response: (a) a depolarization with apparent increase in input conductance; (b) a depolarization with no detectable conductance change; and (c) a hyperpolarization with conductance increase. Some possible mechanisms by which these 3 response-types could be generated are discussed. Depolarizations evoked by the glutamate analogue, kainate, were usually irreversible. Our results emphasize that glutamate and aspartate can evoke a variety of neuronal responses from olfactory cortex neurones. Several of these responses were previously undetected in experiments based on extracellular recordings.

Glycine, GABA and synaptic inhibition of reticulospinal neurones of lamprey

1. Intracellular recordings were made from the cell bodies and axons of giant reticulospinal neurones (Müller cells) of the lamprey and the effects of a variety of putative neurotransmitters tested. Bath-applied acetylcholine, carbamylcholine, norepinephrine, dopamine, histamine and serotonin were without effect. Glycine and gamma-aminobutyric acid (GABA) hyperpolarized and reduced the input resistance of cell bodies but had no effect on the membrane conductance of axons. 2. The threshold dose of bath-applied GABA or glycine for a conductance change in somata was about 0.5 mM and the maximum effect was reached at about 10 mM. The maximum conductance change produced by glycine was always greater than that produced by GABA. 3. Replacement of the sodium in the bathing saline with lithium or choline prolonged the conductance change produced by ionophoretically applied glycine or GABA, suggesting the presence of sodium-dependent uptake systems for glycine and GABA. 4. The reversal potentials for responses to ionophoretically applied glycine and GABA average about --83 mV, the same as that for the inhibitory post-synaptic potential (i.p.s.p.) produced in Müller cells by stimulation of the ipsilateral vestibular nerve. 5. The i.p.s.p. and drug responses appeared to involve an increase in chloride conductance, since their reversal potentials were shifted appropriately by changes in either internal or external chloride. 6. Changes in extracellular potassium concentration also changed i.p.s.p. and drug reversal potentials. However, these effects could be attributed to secondary changes in internal chloride. 7. The receptors for GABA and glycine appeared to be different because of the absence of cross-desensitization and because, at doses below 20 microM, picrotoxin and bicuculline selectively blocked GABA responses while strychnine selectively blocked glycine responses. 8. At concentrations of 20 microM, strychnine eliminated the i.p.s.p. while picrotoxin and bicuculline had no effect. Further, the i.p.s.p. and glycine response of Müller cells located in the isthmic region of the midbrain had the same threshold sensitivity to strychnine. However, the glycine response of other Müller cells was more sensitive to strychnine than was the i.p.s.p. 9. We conclude that glycine is a better candidate for the inhibitory transmitter onto Müller cells than is GABA.