William T. Nickell scite author profile

Dense, focal injections of wheat germ agglutinin conjugated-horseradish peroxidase in the locus coeruleus of rats labeled afferent neurons in unexpectedly few brain regions. Major inputs emanate from only two nuclei--the paragigantocellularis and the prepositus hypoglossi, both in the rostral medulla. The dorsal cap of the paraventricular hypothalamic nucleus and the spinal intermediate gray are possible minor afferents to locus coeruleus. Other areas reported to project to locus coeruleus (for example, amygdala, nucleus tractus solitarius, and spinal dorsal horn) did not exhibit consistent retrograde labeling. Anterograde tracing and electrophysiologic experiments confirmed the absence of input to locus coeruleus from these areas, which instead terminate in targets adjacent to locus coeruleus. These findings redefine the anatomic organization of the locus coeruleus, and have implications for hypotheses concerning the functions of this noradrenergic brain nucleus.

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Chemoanatomical organization of the noradrenergic input from locus coeruleus to the olfactory bulb of the adult rat

McLean

Shipley

Nickell

et al. 1989

J of Comparative Neurology

206

124

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The locus coeruleus contains noradrenergic neurons which project widely throughout the CNS. A major target of locus coeruleus projections in the rat is the olfactory bulb (Shipley et al.: Brain Res. 329:294-299, '85) but the organization of the projections within the bulb has not been systematically examined. In this study, the laminar distribution and densities of locus coeruleus-noradrenergic fibers in the main and accessory olfactory bulbs were determined with anterograde tracing and immunocytochemical techniques.Following iontophoretic injections of 1 % wheat germ agglutinin-horseradish peroxidase into the locus coeruleus, the densest anterograde label in the accessory olfactory bulb was observed in the external plexiform layer, granule cell layer, and especially in the internal part of the mitral cell layer. Virtually no label was observed in the glomerular layer. In the main olfactory bulb, labelled axons were observed in the granule cell layer, in the internal and external plexiform layers, occasionally in the mitral cell layer, and least often in the glomerular layer.Noradrenergic fibers in the olfactory bulb were identified by using immunocytochemistry with an antibody to dopamine-P-hydroxylase. Laminar patterns and densities of noradrenergic innervation were determined with quantitative image analysis. In the accessory olfactory bulb, the densest innervation was in the innermost portion of the mitral cell layer followed by the granule cell layer, the superficial part of the mitral cell layer, and the external plexiform layer. The density of fibers in the glomerular layer was least. The laminar pattern of noradrenergic fiber distribution in the main olfactory bulb was similar to that in accessory olfactory bulb.The present studies demonstrate that locus coeruleus-noradrenergic fibers terminate preferentially in the internal plexiform, granule cell, and external plexiform layers. This suggests that the major influence of the locus coeruleus input to both the main and accessory the olfactory bulbs is on the predominant neuronal element in those layers, the granule cells. Additional studies are needed to resolve how this input influences specific olfactory bulb circuits.

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

Nickell

Behbehani

Shipley

1994

Brain Research Bulletin

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Neuronal Chloride Accumulation in Olfactory Epithelium of Mice Lacking NKCC1

Nickell

Kleene

Gesteland

et al. 2006

Journal of Neurophysiology

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When stimulated with odorants, olfactory receptor neurons (ORNs) produce a depolarizing receptor current. In isolated ORNs, much of this current is caused by an efflux of Cl-. This implies that the neurons have one or more mechanisms for accumulating cytoplasmic Cl- at rest. Whether odors activate an efflux of Cl- in intact olfactory epithelium, where the ionic environment is poorly characterized, has not been previously determined. In mouse olfactory epithelium, we found that >80% of the summated electrical response to odors is blocked by niflumic acid or flufenamic acid, each of which inhibits Ca2+-activated Cl- channels in ORNs. This indicates that ORNs accumulate Cl- in situ. Recent evidence has shown that NKCC1, a Na+-K+-2Cl- cotransporter, contributes to Cl- accumulation in mammalian ORNs. However, we find that the epithelial response to odors is only reduced by 39% in mice carrying a null mutation in Nkcc1. As in the wild-type, most of the response is blocked by niflumic acid or flufenamic acid, indicating that the underlying current is carried by Cl-. We conclude that ORNs effectively accumulate Cl- in situ even in the absence of NKCC1. The Cl- -transport mechanism underlying this accumulation has not yet been identified.

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Mechanisms of neuronal chloride accumulation in intact mouse olfactory epithelium

Nickell

Kleene

2007

The Journal of Physiology

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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 − /HCO 3 − 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 − /HCO 3 − 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.

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