Paul Q. Trombley

Excitatory actions of GABA in developing rat hypothalamic neurones.

1. Gramicidin‐perforated patch clamp recording was employed to study GABA‐mediated responses in rat hypothalamic neurones (n = 102) with an intracellular Cl‐ concentration unaltered by the pipette solution. 2. In young cultures after 1‐7 days in vitro (DIV), GABA induced depolarizing membrane potentials (+16.5 +/‐ 1.3 mV) that often surpassed the threshold for the firing of action potentials (‐42 +/‐ 1 mV) and resulted in an increase in neuronal activity. The depolarizing responses to GABA in young cultures were dose dependent. The concentration of GABA necessary to evoke the half‐maximal depolarization (EC50) was 2.8 microM. In contrast, GABA induced hyperpolarizing membrane potentials (‐12.0 +/‐ 1.4 mV) and a decrease in neuronal activity in older neurones (20‐33 DIV). Both the depolarization and the hyperpolarization induced by GABA were blocked by bicuculline, indicating a mediation by GABAA receptors. 3. The reversal potentials of the GABA‐evoked currents were between ‐40 to ‐50 mV during the first week of culture, and shifted to below ‐70 mV after 3 weeks of culture. In parallel, neurones that were dissociated from older animals (postnatal day 5) had a more negative reversal potential for the GABA‐evoked currents than cells from younger animals (embryonic day 15), suggesting that the negative shift of the reversal potential occurs both in vitro and in vivo. Our data suggest that the mechanism for GABA‐induced depolarization is the depolarized Cl‐ reversal potential found in young but not older neurones. 4. Consistent with the depolarizing response to exogenous application of GABA, some spontaneous depolarizing postsynaptic potentials in young cultures were insensitive to AP5‐CNQX, but were eliminated by bicuculline, indicating that synaptically released GABA mediated excitatory synaptic transmission in early development. 5. By combining a rapid computer‐controlled delivery of GABA with subthreshold positive current injections into recorded neurones, we found in young cultures that the GABA‐evoked depolarization could directly trigger action potentials, facilitate some depolarizing input to fire action potentials, and shunt other depolarizing input. Whether the GABA‐induced depolarization is excitatory or inhibitory would be determined by the reversal potential of the GABA‐evoked current, and the temporal relationship between GABA‐evoked depolarizations and other excitatory events. 6. We conclude that the reversal potential of the GABA‐evoked current shifts negatively from depolarizing to hyperpolarizing in developing hypothalamus. Consequently, GABA neurotransmission may serve both excitatory and inhibitory roles during early development.

Endogenous mechanisms of neuroprotection: role of zinc, copper, and carnosine.

Zinc and copper are endogenous transition metals that can be synaptically released during neuronal activity. Synaptically released zinc and copper probably function to modulate neuronal excitability under normal conditions. However, zinc and copper also can be neurotoxic, and it has been proposed that they may contribute to the neuropathology associated with a variety of conditions, such as Alzheimers disease, stroke, and seizures. Recently, we demonstrated that carnosine, a dipeptide expressed in glial cells throughout the brain as well as in neuronal pathways of the visual and olfactory systems, can modulate the effects of zinc and copper on neuronal excitability. This result led us to hypothesize that carnosine may modulate the neurotoxic effects of zinc and copper as well. Our results demonstrate that carnosine can rescue neurons from zinc- and copper-mediated neurotoxicity and suggest that one function of carnosine may be as an endogenous neuroprotective agent.

Dopaminergic modulation at the olfactory nerve synapse.

Dopamine can change the membrane potential, regulate cyclic nucleotides, and modulate transmitter release in central neurons. In the olfactory bulb (OB), the dopamine synthetic enzyme, tyrosine hydroxylase, is largely confined to neurons in the glomerular layer. After demonstrating dopamine D2 receptors in the glomerular and olfactory nerve (ON) layers, Nickell et al. [W.T. Nickell, A.B. Norman, L.M. Wyatt, M.T. Shipley, Olfactory bulb DA receptors may be located on terminals of the olfactory nerve, NeuroReport, 2 (1991) 9-12.] proposed that these receptors may reduce transmitter release due to their localization to ON presynaptic boutons. We have previously demonstrated that olfactory receptor neurons use glutamate to excite OB neurons through activation of glutamate receptors subtypes, NMDA and AMPA/kainate [D.A. Berkowicz, P.Q. Trombley, G.M. Shepherd, Evidence for glutamate as the olfactory receptor cell neurotransmitter. J. Neurophysiol., 71 (1994) 2557-2561]. Here, we used a hemisected turtle OB preparation and patch-clamp recording techniques to assess dopamine modulation of the ON/OB neuron synapse. We found that dopamine (10-300 microM) reversibly decreased the excitatory postsynaptic response to ON stimulation. This effect could be overcome by recruiting additional nerve fibers by increasing the intensity of ON stimulation. Quinpirole (10 microM), a D2 agonist, mimicked the effects of dopamine. Conversely, sulpiride (300 microM), a D2 antagonist, prevented the inhibitory effects of dopamine on synaptic transmission. Whereas dopamine appeared to equally affect the NMDA and AMPA/kainate receptor-mediated components of the synaptically evoked response, it had no direct effect on membrane currents evoked by exogenous glutamate, kainate or NMDA applied to cultured OB neurons. Our data, therefore, support the notion that dopamine modulates synaptic transmission between olfactory receptor neurons and OB neurons via a presynaptic mechanism involving D2 receptor activation. Our abstract (Berkowicz et al. (1994) Neuroscience Abs. 20:328) is the first report of these results.

Synaptic transmission and modulation in the olfactory bulb.

Recent work in molecular biology and synaptic physiology has significantly increased our understanding of inhibitory and excitatory mechanisms in the olfactory bulb. Multiple subtypes of amino acid receptors with different functional and neuromodulatory properties are likely to play key roles in processing odor information transduced and relayed to the olfactory bulb by the olfactory sensory neurons, and in modulating that information during olfactory learning.

The role of norepinephrine in plasticity of visual cortex.

Abbreviations

Embryonic hypothalamic expression of functional glutamate receptors

Glutamate can play a number of roles in the developing brain, including modulation of gene expression, cell motility, neurite growth and neuronal survival, all critical for the final organization and function of the mature brain. These functions are dependent on the early expression of glutamate receptors and on glutamate release in developing neurons. This subject has received little attention in the hypothalamus, despite glutamates critical role as an excitatory transmitter in hypothalamic control of circadian rhythms, endocrine secretion, temperature regulation, and autonomic control. A total of 10,922 rat hypothalamic neurons were studied with digital Ca2+ imaging with the ratiometric dye fura-2 to examine their responses to glutamate receptor agonists and antagonists during embryonic development and maturation in vitro. Functional glutamate receptors were found very early in development (embryonic day 15-E15) with both Ca2+ imaging and with patch clamp recording. This is a time when the hypothalamus is beginning to undergo neurogenesis. Ca2+ responses from N-methyl-D-aspartate receptors developed later than those from non-N-methyl-D-aspartate ionotropic receptors that responded to kainate and alpha-amino-3-hydroxy-5-methyl-4-isoxazoleproprionate. The responses of immature E15 cells after one day in vitro were compared with more mature cells after six days in vitro to examine the response to repeated 3 min applications of 100 microM kainate (n = 108). Immature cells showed similar Ca2+ rises (+232nM Ca2+) with each kainate stimulation. In contrast, more mature cells showed an initial Ca2+ rise of 307 nM, with the second rise only to 147 nM above the initial baseline. Immature cells more quickly returned to their pre-kainate baseline than did older cells. The expression of metabotropic glutamate receptors was studied with the selective agonist trans-1-amino-cyclopentyl-1,3-dicarboxylic acid and with glutamate stimulation in the absence of extracellular Ca2+ and presence of 1 mM EGTA. After five days in vitro. E16 astrocytes showed a greater response than did neurons to conditions that would activate the metabotropic glutamate receptor. A dramatic increase in the percentage of cells that responded to N-methyl-D-aspartate was found after only a few days in culture. Only a small number of E15 cells studied on the day of culture (4% of 694 cells) showed a response to 100 microM N-methyl-D-aspartate. Thirty-eight percent of 120 E18 cells cultured for one day in vitro showed an N-methyl-D-aspartate response.(ABSTRACT TRUNCATED AT 400 WORDS)

Carnosine modulates zinc and copper effects on amino acid receptors and synaptic transmission

CARNOSINE is a dipeptide which is highly concentrated in mammalian olfactory sensory neurons along with zinc and/or copper, and glutamate. Although carnosine has been proposed as a neurotransmitter or neuromodulator, no specific function for carnosine has been identified. We used whole-cell current- and voltage-clamp recording to examine the direct effects and neuromodulatory actions of carnosine on rat olfactory bulb neurons in primary culture. Carnosine did not evoke a membrane current or affect currents evoked by glutamate, GABA or glycine. Copper and zinc inhibited NMDA and GABA receptor-mediated currents and inhibited synaptic transmission. Carnosine prevented the actions of copper and reduced the effects of zinc. These results suggest that carnosine may indirectly influence neuronal excitability by modulating the effects of zinc and copper.

Noradrenergic modulation of synaptic transmission between olfactory bulb neurons in culture: Implications to olfactory learning

Noradrenergic modulation of the glutamatergic-GABAergic synapses between mitral/tufted (M/T) and granule cells has been implicated in some forms of olfactory learning (5), but the mechanism of action is unknown. Intracellular stimulation of M/T cells in primary culture, evoked glutamate-mediated excitatory postsynaptic potentials (EPSPs) in granule cells that were reversibly inhibited by approximately 50% during application of norepinephrine (NE). NE had no effect, however, on the membrane current evoked by the application of glutamate, indicating a presynaptic site of action. The effect of NE on EPSPs was mimicked by the alpha receptor agonist clonidine, but not by the beta receptor agonist isoproteronol. NE also inhibited spontaneous GABAergic inhibitory postsynaptic potentials recorded in M/T cells, by a presynaptic alpha-adrenergic mediated mechanism. NE and clonidine also inhibited high threshold calcium currents. The effects of NE on calcium currents were irreversible in the presence of internal GTP gamma S and prevented by pertussis toxin, suggesting a G protein-coupled mechanism. Pertussis toxin also prevented the effects of NE on synaptic transmission. These results support previous results suggesting a disinhibitory role for NE in the olfactory bulb. This action is, at least in part, due to a reduction in mitral cell mediated granule cell excitation through inhibition of presynaptic calcium influx.

Diverse modulation of olfactory bulb AMPA receptors by zinc.

Increasing evidence suggests that zinc modulates synaptic transmission in the olfactory bulb and other brain regions. We investigated the sensitivity of AMPA receptors on the bulbs two primary neuronal populations to several concentrations of zinc. Zinc (30–1000 μM) was coapplied to mitral/tufted cells and interneurons during AMPA-evoked currents, and current responses (potentiation, inhibition, no effect) were analyzed. Both neuronal populations expressed zinc-sensitive and zinc-insensitive AMPA receptors. However, the frequency and magnitude of zincs effects varied with cell type. In addition, zinc did not always have biphasic effects at AMPA receptors (potentiation at low concentrations; inhibition at high concentrations), as reported in other brain regions. Zincs diverse effects suggest that zinc may alter odor information processing by differential modulation of excitatory circuits.

Dopamine: A Modulator of Circadian Rhythms in the Central Nervous System

Circadian rhythms are daily rhythms that regulate many biological processes – from gene transcription to behavior – and a disruption of these rhythms can lead to a myriad of health risks. Circadian rhythms are entrained by light, and their 24-h oscillation is maintained by a core molecular feedback loop composed of canonical circadian (“clock”) genes and proteins. Different modulators help to maintain the proper rhythmicity of these genes and proteins, and one emerging modulator is dopamine. Dopamine has been shown to have circadian-like activities in the retina, olfactory bulb, striatum, midbrain, and hypothalamus, where it regulates, and is regulated by, clock genes in some of these areas. Thus, it is likely that dopamine is essential to mechanisms that maintain proper rhythmicity of these five brain areas. This review discusses studies that showcase different dopaminergic mechanisms that may be involved with the regulation of these brain areas’ circadian rhythms. Mechanisms include how dopamine and dopamine receptor activity directly and indirectly influence clock genes and proteins, how dopamine’s interactions with gap junctions influence daily neuronal excitability, and how dopamine’s release and effects are gated by low- and high-pass filters. Because the dopamine neurons described in this review also release the inhibitory neurotransmitter GABA which influences clock protein expression in the retina, we discuss articles that explore how GABA may contribute to the actions of dopamine neurons on circadian rhythms. Finally, to understand how the loss of function of dopamine neurons could influence circadian rhythms, we review studies linking the neurodegenerative disease Parkinson’s Disease to disruptions of circadian rhythms in these five brain areas. The purpose of this review is to summarize growing evidence that dopamine is involved in regulating circadian rhythms, either directly or indirectly, in the brain areas discussed here. An appreciation of the growing evidence of dopamine’s influence on circadian rhythms may lead to new treatments including pharmacological agents directed at alleviating the various symptoms of circadian rhythm disruption.