William T. Nickell

OLFACTORY RECEPTOR NEURONS EXPRESS D2 DOPAMINE RECEPTORS

The role of the dopamine (DA) in the olfactory bulb (OB) was explored by determining which of the potential target cells express dopamine receptors (DARs). Previously, it was reported that D2‐like DAR (D2, D3, and D4 subtypes) radioligand binding is restricted to the outer layers of the OB. The neuronal elements present only in these layers are the axons of the olfactory receptor neurons (ORNs) and the juxtaglomerular (JG) neurons of the glomerular layer. Based on this pattern of D2‐like ligand binding, it was suggested that D2‐like receptors might be located presynaptically on ORN terminals. The present study was undertaken to investigate this hypothesis. In the outer bulb layers of rats in which the ORNs were destroyed by nasal lavage with ZnSO4, D2‐like radioligand binding was reduced severely. The receptor subtype D2 mRNA, but not D3 mRNA, was detected in adult rat olfactory epithelial tissue. By using in situ hybridization, this D2 mRNA was located preferentially in epithelial layers that contain ORN perikarya. D2 mRNA was eliminated after bulbectomy, a manipulation known to cause retrograde degeneration of the mature ORNs. Taken together, the surgical manipulations indicate that mature ORNs express D2 DARs and are consistent with the hypothesis that functional receptors are translocated to their axons and terminals in the bulb. This suggests that dopamine released from JG interneurons could be capable of presynaptically influencing neurotransmission from the olfactory nerve terminals to OB target cells through the D2 receptor. J. Comp. Neurol. 411:666–673, 1999.

Olfactory bulb DA receptors may be located on terminals of the olfactory nerve.

The glomerular layer of the olfactory bulb contains a substantial population of dopaminergic neurons. We determined the quantity and location of D1 and D2 dopamine receptors which are the presumed targets of these neurons. Binding of the D1 selective ligand [3H]SCH23390 was slightly above background and was distributed through all layers of the bulb except the olfactory nerve layer. In contrast there were relatively high levels of [3H]spiperone binding to D2 DA receptors in the glomerular and olfactory nerve layers. The presence of relatively high concentrations of D2 DA receptors in both the nerve layer and glomerular layer suggests the novel hypothesis that these receptors may be localized on terminals of the olfactory nerve.

Mechanisms of neuronal chloride accumulation in intact mouse olfactory epithelium

When olfactory receptor neurons respond to odours, a depolarizing Cl− efflux is a substantial part of the response. This requires that the resting neuron accumulate Cl− against an electrochemical gradient. In isolated olfactory receptor neurons, the Na+–K+–2Cl− cotransporter NKCC1 is essential for Cl− accumulation. However, in intact epithelium, a robust electrical olfactory response persists in mice lacking NKCC1. This response is largely due to a neuronal Cl− efflux. It thus appears that NKCC1 is an important part of a more complex system of Cl− accumulation. To identify the remaining transport proteins, we first screened by RT‐PCR for 21 Cl− transporters in mouse nasal tissue containing olfactory mucosa. For most of the Cl− transporters, the presence of mRNA was demonstrated. We also investigated the effects of pharmacological block or genetic ablation of Cl− transporters on the olfactory field potential, the electroolfactogram (EOG). Mice lacking the common Cl−/HCO3− exchanger AE2 had normal EOGs. Block of NKCC cotransport with bumetanide reduced the EOG in epithelia from wild‐type mice but had no effect in mice lacking NKCC1. Hydrochlorothiazide, a blocker of the Na+–Cl− cotransporter, had only a small effect. DIDS, a blocker of some KCC cotransporters and Cl−/HCO3− exchangers, reduced the EOG in epithelia from both wild‐type and NKCC1 knockout mice. A combination of bumetanide and DIDS decreased the response more than either drug alone. However, no combination of drugs completely abolished the Cl− component of the response. These results support the involvement of both NKCC1 and one or more DIDS‐sensitive transporters in Cl− accumulation in olfactory receptor neurons.

Evidence for GABAB-mediated inhibition of transmission from the olfactory nerve to mitral cells in the rat olfactory bulb

The GABAB agonist baclofen blocks transmission from the olfactory nerve to second order neurons in the frog olfactory bulb, and GABAB receptors in the rat olfactory bulb are selectively located in the glomerular layer. A reasonable hypothesis, therefore, is that inhibition in the glomerular layer is mediated, at least in part, by GABAB receptors. Here, we investigated the role of GABAB receptors in regulating the responses of mitral cells to activation of the olfactory nerve in the rat. Topical application of baclofen to the surface of the rat olfactory bulb reduced the amplitude of field potentials evoked by olfactory nerve stimulation (orthodromic response). Baclofen reduced the orthodromic response in a dose-dependent manner but the drug had no effect on the field potential evoked by antidromic activation of mitral cell axons (antidromic response). Baclofen also reduced olfactory nerve-evoked responses of mitral cells in an olfactory bulb slice preparation. The pharmacological specificity of the inhibition was confirmed by showing that the GABAB antagonist, CGP 55845A, blocked the inhibitory action of baclofen. These results suggest that transmission from olfactory nerve terminals to second order neurons is negatively regulated by periglomerular GABAergic interneurons; this inhibition is mediated, at least partially, by GABAB receptors.

Brain norepinephrine reductions in soman-intoxicated rats : association with convulsions and AChE inhibition, time course, and relation to other monoamines

The organophosphate chemical nerve agent, soman, causes convulsions, neuropathology, and, ultimately, death. A major problem in treating soman intoxication is that peripherally acting pharmacological agents which prevent death do not prevent seizures. Although a primary cause of these symptoms is the excess of acetylcholine which follows acetylcholinesterase (AChE) inhibition, centrally acting muscarinic blockers, such as atropine, alleviate, but do not block, the convulsive actions of soman. Moreover, there is a relatively weak relationship between CNS reductions of AChE and the incidence of convulsions. There is evidence suggesting that soman intoxication stimulates the release of norepinephrine (NE) in the brain. Recent evidence has implicated NE in the induction and/or maintenance of seizures. Thus, in the present study the relations among soman-induced convulsions, AChE inhibition, and brain NE and other monoamine changes were examined. The time course of brain NE recovery was also determined. Rats were injected (im) with a single dose (78 micrograms/kg) of soman. At this dose 68% of the injected rats developed convulsions. Both convulsive and nonconvulsive rats were sacrificed between 1 and 96 h following soman injection and NE levels in the rostral forebrain and olfactory bulb were determined by HPLC with electrochemical detection. In all convulsive rats NE levels declined substantially. Forebrain NE levels were decreased by 50% at 1 h and 70% at 2 h following soman injection. Recovery of NE began at 8 h and was complete by 96 h following soman administration. Although nonconvulsive rats showed other signs of intoxication, NE levels in these rats were unchanged. Dopamine (DA) and serotonin (5-HT) levels were not significantly affected in either convulsive or nonconvulsive rats. However, 5-hydroxyindoleacetic acid, the major metabolite of 5-HT, and homovanillic acid and 3,4-dihydroxyphenylacetic acid, the two major metabolites of DA, were increased significantly in the forebrain of convulsive, but not nonconvulsive rats, indicating an increase in 5-HT and DA turnover. However, in contrast to the abrupt decline in NE, these increases in DA and 5-HT metabolites were slow and progressive. Taken together, the present results and other recent findings suggest that rapid, sustained NE release could play a role in the induction and/or maintenance of soman-induced convulsions, whereas increased release of 5-HT and DA may be a consequence of seizures. Further investigation of the role of NE in soman-induced convulsions may lead to improved treatment of soman intoxication and a better understanding of the role of NE in other forms of seizures, including human epilepsy.

Orthodromic synaptic activation of rat olfactory bulb mitral cells in isolated slices

Axons of olfactory receptor neurons terminate in the glomerular layer of the olfactory bulb, where they synapse with the apical dendrites of mitral cells. Although the mitral cell and its excitation by the olfactory nerve have been the subject of numerous experimental investigations, in vitro studies of these neurons have primarily used nonmammalian preparations. We have recorded the responses of rat olfactory bulb mitral cells to stimulation of the olfactory nerve layer in vitro using extracellular and whole cell patch techniques. Olfactory bulbs were cut into 400-microns thick slices in approximately horizontal section and submerged in a recording chamber. Patch clamp electrodes were guided into the mitral cell layer, which was visible under a dissecting microscope. A stimulating electrode was placed onto the olfactory nerve layer (ONL) rostral to the recording electrode. In extracellular recordings, mitral cells typically responded to ONL stimulation with a prolonged excitation lasting 1 s or longer. With whole cell patch recordings, membrane resistances (mean 272 M omega) were substantially higher than those reported in previous intracellular studies that used sharp electrodes. Small spontaneous excitatory potentials were present in some mitral cells. ONL stimulation caused a prolonged depolarization comparable to the duration of the period of excitation observed in extracellular recordings. At membrane potentials near -55 mV, ONL stimulation evoked a train of spikes. All but the first of these spikes were blocked by hyperpolarization of the membrane to -65 mV.

Neurophysiology of the Olfactory Bulb

The olfactory bulb receives neural signals from a sheet of sensory epithelium located in the nasal cavity and transforms this information into output signals that are transmitted to central cortical structures. The olfactory system is thus similar to other sensory systems in that a two-dimensional array of receptors projects upon a two-dimensional cortex. It differs, however, in having no obvious inherent relation between odor characteristics and the receptive surface. One hypothesis for the neural coding of odor quality is that there are a finite number of olfactory receptor subtypes, each responsive to some particular property of odorous molecules. Different odors would generate distinctive patterns of responses across the several receptor types. These hypothetical receptor types might be segregated into separate regions of the epithelium, and this segregation might be conveyed topographically to the olfactory bulb, but there is no necessity of this.

Single ionic channels of two Caenorhabditis elegans chemosensory neurons in native membrane.

The genome of Caenorhabditis elegans contains representatives of the channel families found in both vertebrate and invertebrate nervous systems. However, it lacks the ubiquitous Hodgkin-Huxley Na+ channel that is integral to long-distance signaling in other animals. Nematode neurons are presumed to communicate by electrotonic conduction and graded depolarizations. This fundamental difference in operating principle may require different channel populations to regulate transmission and transmitter release. We have sampled ionic channels from the somata of two chemosensory neurons (AWA and AWC) of C. elegans. A Ca2+-activated, outwardly rectifying channel has a conductance of 67 pS and a reversal potential indicating selectivity for K+. An inwardly rectifying channel is active at potentials more negative than -50 mV. The inward channel is notably flickery even in the absence of divalent cations; this prevented determination of its conductance and reversal potential. Both of these channels were inactive over a range of membrane potentials near the likely cell resting potential; this would account for the region of very high membrane resistance observed in whole-cell recordings. A very-large-conductance (> 100 pS), inwardly rectifying channel may account for channel-like fluctuations seen in whole-cell recordings.

Dielectric Properties of Cured Burley Tobacco

ABSTRACT TOBACCO resembles other dehydrated vegetable products in its electrical properties. Tobacco appears to be electrically inert below about 14 percent moisture content dry basis (mcdb). The dielectric constant in-creased with moisture content and decreased with fre-quency. Both the dielectric constant and AC conductivity are reliable functions of moisture from 200 Hz to 50 MHz when sample temperature and density are constant.