Neuromodulatory effects of gonadotropin releasing hormone on olfactory receptor neurons.

The terminal nerve is an anterior cranial nerve that innervates the lamina propria of the chemosensory epithelia of the nasal cavity. The function of the terminal nerve is ambiguous, but it has been suggested to serve a neuromodulatory role. We tested this hypothesis by exposing olfactory receptor neurons from mudpuppies (Necturus maculosus) to a peptide, gonadotropin releasing hormone (GnRH), that is found in cells and fibers of the terminal nerve. We used voltage-clamped whole-cell recordings to examine the effects of 0. 5-50 micrometer GnRH on voltage-activated currents in olfactory receptor neurons from epithelial slices. We found that GnRH increases the magnitude, but does not alter the kinetics, of a tetrodotoxin-sensitive inward current. This increase in magnitude generally begins 5-10 min after initial exposure to GnRH, is sustained for at least 60 min during GnRH exposure, and recovers to baseline within 5 min after GnRH is washed off. This effect occurred in almost 60% of the total number of olfactory receptor neurons examined and appeared to be seasonal: approximately 67% of neurons responded to GnRH during the courtship and mating season, compared with approximately 33% during the summer, when the sexes separate. GnRH also appears to alter an outward current in the same cells. Taken together, these data suggest that GnRH increases the excitability of olfactory receptor neurons and that the terminal nerve functions to modulate the odorant sensitivity of olfactory receptor neurons.

A cyclic nucleotide-dependent chloride conductance in olfactory receptor neurons.

Whole-cell membrane currents were recorded from olfactory receptor neurons from the neotenic salamander Necturus maculosus. Cyclic nucleotides, released intracellularly by flash photolysis of NPE-caged cAMP or NPE-caged cGMP, activated a transient chloride current. The chloride current could be elicited at constant voltage in the absence of extracellular Ca2+ as well as in the presence of 3 mM intracellular Ca2+, suggesting that the current did not require either voltage or Ca2+ transients for activation. The current could be elicited in the presence of the protein kinase inhibitors H-7 and H-89, and in the absence of intracellular ATP, indicating that activation was independent of protein kinase A activity. These results suggest that Necturus olfactory receptor neurons contain a novel chloride ion channel that may be directly gated by cyclic nucleotides.

Transduction diversity in olfaction.

Odors are powerful stimuli that can focus the attention, elicit behaviors (or misbehaviors) and even resurrect forgotten memories. These actions are directed by the central nervous system, but they depend upon the initial transduction of chemical signals by olfactory receptor neurons. Electrophysiological recordings suggest that the responses of olfactory receptor neurons to odors are more diverse than was initially believed, being mediated by effects on several different conductances. Both excitatory and inhibitory responses are produced by these effects and some, if not all, odors can affect more than one component of the membrane conductance. The extent of this diversity is reviewed here, and its impact on our understanding of odor discrimination is discussed.

VIP modulates neuronal nicotinic acetylcholine receptor function by a cyclic AMP-dependent mechanism.

Neuronal nicotinic ACh receptors (AChRs) mediate synaptic transmission throughout the nervous system, and are regulated by cellular processes and interactions that include second messenger signaling pathways. In the case of chick ciliary ganglion neurons, activation of the cAMP-dependent signaling pathway with cAMP analogs enhances ACh sensitivity in a manner consistent with an increase in the number of functional nicotinic receptors. We have now identified vasoactive intestinal peptide (VIP) as a neuromodulator or "first messenger" in the cAMP-mediated pathway that regulates neuronal AChRs. Using cAMP imaging and biochemical detection assays, we find that bath application of VIP elevates intracellular cAMP in freshly isolated ciliary ganglion neurons within minutes. The VIP treatment also enhances neuronal ACh sensitivity assessed with whole-cell recording. The enhanced ACh sensitivity produced by VIP appears with a short latency, similar to that associated with the increase in cAMP, and is not additive with the enhanced ACh sensitivity produced by bath application of a cAMP analog. In contrast, calcitonin gene-related peptide (CGRP), known to regulate muscle nicotinic AChRs via a cAMP-dependent pathway, has no detectable effect on levels of either cAMP or ACh sensitivity in the neurons. The results indicate that VIP enhances the ACh sensitivity of ciliary ganglion neurons via a cAMP-dependent signaling pathway, presumably by interaction with a specific receptor. Since VIP-like immunoreactivity is present in the presynaptic nerve terminals of avian ciliary ganglia, a VIP-like peptide could modulate AChRs in vivo.

Cellular mechanisms mediating agonist-stimulated calcium influx in the pancreatic acinar cell.

Figure 1 summarizes our current concept of a signaling mechanism to explain agonist-induced Ca2+ entry in the pancreatic acinar cell. We propose that cGMP can modulate Ca2+ entry under conditions of internal Ca2+ store depletion and that the NO signaling system may be involved in coupling Ca2+ depletion to cGMP formation. The finding that Ca2+ entry after Ca2+ store depletion can occur with no elevation in [Ca2+]i37 raises the possibility that alternative signaling pathways may converge to stimulate cGMP formation or that additional messengers may activate plasmalemmal Ca2+ entry mechanisms in parallel.

Action potentials and chemosensitive conductances in the dendrites of olfactory neurons suggest new features for odor transduction.

Odors affect the excitability of an olfactory neuron by altering membrane conductances at the ciliated end of a single, long dendrite. One mechanism to increase the sensitivity of olfactory neurons to odorants would be for their dendrites to support action potentials. We show for the first time that isolated olfactory dendrites from the mudpuppy Necturus maculosus contain a high density of voltage-activated Na+ channels and produce Na-dependent action potentials in response to depolarizing current pulses. Furthermore, all required steps in the transduction process beginning with odor detection and culminating with action potential initiation occur in the ciliated dendrite. We have previously shown that odors can modulate Cl- and K+ conductances in intact olfactory neurons, producing both excitation and inhibition. Here we show that both conductances are also present in the isolated, ciliated dendrite near the site of odor binding, that they are modulated by odors, and that they affect neuronal excitability. Voltage-activated Cl- currents blocked by 4,4'-diisothiocyanatostilbene-2,2' disulfonic acid and niflumic acid were found at greater than five times higher average density in the ciliated dendrite than in the soma, whereas voltage-activated K+ currents inhibited by intracellular Cs+ were distributed on average more uniformly throughout the cell. When ciliated, chemosensitive dendrites were stimulated with the odorant taurine, the responses were similar to those seen in intact cells: Cl- currents were increased in some dendrites, whereas in others Cl- or K+ currents were decreased, and responses washed out during whole-cell recording. The Cl- equilibrium potential for intact neurons bathed in physiological saline was found to be -45 mV using an on-cell voltage-ramp protocol and delayed application of channel blockers. We postulate that transduction of some odors is caused by second messenger-mediated modulation of the resting membrane conductance (as opposed to a specialized generator conductance) in the cilia or apical region of the dendrite, and show how this could alter the firing frequency of olfactory neurons.

Modulation by albumin of neuronal cholinergic sensitivity.

Bovine serum albumin greatly enhanced the cholinergic response mediated by neuronal nicotinic acetylcholine receptors in chick ciliary ganglion neurons. The enhancement exceeded 5-fold in some experiments (mean +/- standard error, 3.26 +/- 0.43-fold) and was rapid, was dose dependent, and occurred without changes in the unitary conductance or the mean open time of the acetylcholine receptor channel. This lack of detectable change in permeation or kinetic properties suggests that bovine serum albumin might increase acetylcholine responses by increasing the number of functional receptors. The enhancement appears to be specific to the albumin molecule, because activity could not be removed by detergent extraction, gel filtration, or dialysis. Acetylcholine responses in these cells are known to be enhanced by a cAMP-dependent mechanism that converts existing acetylcholine receptors from a nonfunctional to a functional state. We found that the enhancement by bovine serum albumin occurred without an increase in cAMP and that pretreatment with membrane-permeable cAMP analogs prevented any additional enhancement of the cholinergic response by bovine serum albumin. These observations are consistent with a cAMP-dependent modulation of the enhancement produced by bovine serum albumin or a convergence of the two enhancement mechanisms onto a single pathway.

Cyclic GMP modulates depletion-activated Ca2+ entry in pancreatic acinar cells.

In the pancreatic acinar cell, hormonal stimulation causes a rise in the intracellular free Ca2+ concentration by activating the inositol 1,4,5-trisphosphate-mediated release of Ca2+ from intracellular stores (Berridge, M. J., and Irvine, R. F. (1989) Nature 341, 197-205). The released Ca2+ is, for the most part, extruded from the cell, necessitating a mechanism for Ca2+ entry and reloading of intracellular Ca2+ stores (Putney, J. W., Jr. (1990) Cell Calcium 11, 611-624; Rink, T. J. (1990) FEBS Lett. 268, 381-385). However, neither the mechanism of depletion-activated Ca2+ entry nor the signal that activates it is known. We report here that a sustained inward current of depletion-activated Ca2+ entry can be measured in pancreatic acinar cells using patch-clamp recording methods. Furthermore, the current can be blocked by an inhibitor of guanylyl cyclase, can be reactivated by 8-bromo-cGMP after inhibition, and can be activated in the absence of Ca2+ depletion by perfusing the cell with cGMP, but not cAMP. Intracellular perfusion with 1,3,4,5-inositol tetrakisphosphate did not activate an inward current, whereas perfusion with 2,4,5-inositol trisphosphate did activate an inward current. We conclude that cGMP may be an intracellular messenger that regulates depletion-activated Ca2+ entry.

Modulation of Cl-, K+, and nonselective cation conductances by taurine in olfactory receptor neurons of the mudpuppy Necturus maculosus.

Odors are transduced by processes that modulate the membrane conductance of olfactory receptor neurons. Olfactory neurons from the aquatic salamander, Necturus maculosus, were acutely isolated without enzymes and studied with a resistive whole-cell method to minimize loss of soluble intracellular constituents. 55 of 224 neurons responded to the test compound taurine at concentrations between 10 nM and 100 microM. Four different conductance changes were elicited by taurine: an increased Cl- conductance (33%), an increased nonselective cation conductance (15%), a decreased Cl- conductance (15%), and a decreased K+ conductance (15%); in addition, responses too small to be characterized were elicited in some neurons. In most cases, taurine appeared to modulate only a single conductance in any particular cell. Modulation of each conductance was dose dependent, and each response ran down quickly in the normal whole-cell mode, presumably due to washout of a diffusible component in the transduction pathway. Modulation of taurine-sensitive conductances caused either inhibitory or excitatory responses. A similar diversity of responses in vivo would produce a complex pattern of electrical activity that could encode the identity and characteristics of an odor.

Spatial pattern of receptor expression in the olfactory epithelium.

A PCR-based strategy for amplifying putative receptors involved in murine olfaction was employed to isolate a member (OR3) of the seven-transmembrane-domain receptor superfamily. During development, the first cells that express OR3 appear adjacent to the wall of the telencephalic vesicle at embryonic day 10. The OR3 receptor is uniquely expressed in a subset of olfactory cells that have a characteristic bilateral symmetry in the adult olfactory epithelium. This receptor and its specific pattern of expression may serve a functional role in odor coding or, alternatively, may play a role in the development of the olfactory system.

Chemosensory responses in isolated olfactory receptor neurons from Necturus maculosus.

Olfactory receptor neurons were isolated without enzymes from the mudpuppy, Necturus maculosus, and tested for chemosensitivity. The cells responded to odorants with changes in firing frequency and alterations in excitability that were detected with tight-seal patch electrodes using on-cell and whole-cell recording conditions. Chemosensitive cells exhibited two primary response characteristics: excitation and inhibition. Both types of primary response were observed in different cells stimulated by mixtures of amino acids as well as by the single compound L-alanine, suggesting that there may be more than one transduction pathway for some odorants. Using the normal whole-cell recording method, the chemosensitivity of competent cells washed out rapidly; a resistive whole-cell method was used to record odorant responses under current-clamp conditions. In response to chemical stimulation, excitability appeared to be modulated in several different ways in different cells: odorants induced hyperpolarizing or depolarizing receptor potentials, elicited or inhibited transient, rhythmic generator potentials, and altered excitability without changing the membrane potential or input resistance. These effects suggest that olfactory transduction is mediated through at least three different pathways with effects on four or more components of the membrane conductance. Polychotomous pathways such as these may be important for odor discrimination and for sharpening the "odor image" generated in the olfactory epithelium.

Multiple voltage-sensitive K+ channels regulate dendritic excitability in cerebellar Purkinje neurons.

Ionic conductances present in the dendritic region of the cerebellar Purkinje neuron were studied using the single-channel and whole-cell recording methods. Several types of voltage-sensitive K+ channels including a Ca2+ activated K+ channel were found to be a prominent components of the dendritic membrane. All patches studied contained K+ channel types and most patches contained more than one K+ channel type. In cell attached recordings, K+ channel activity was associated with the late phase of spontaneous action potentials suggesting a functional relationship. These data demonstrate that voltage-sensitive ion channels contribute to dendritic excitability and suggest that the transduction and integration of synaptic signals may involve both active and passive ionic conductances.

Two types of nicotinic acetylcholine receptor channels at slow fibre end-plates of the garter snake.

1. Two different types of acetylcholine receptor channels can be detected on the post-junctional membrane of slow muscle fibres in garter snakes. Here they are designated T-type and S-type channels. Only T-type channels can also be found at twitch fibre neuromuscular junctions. 2. The physiological properties of slow fibre T-type channels are similar to those of acetylcholine receptor channels in end-plates of twitch fibres in these animals. 3. S-type channels had a smaller conductance than T-type channels (32 vs. 49 pS), but a similar reversal potential near 0 mV. 4. Both S- and T-type channels were found together in most patches of slow fibre end-plate membrane, but some patches displayed just one type or the other. 5. The activity of both S- and T-type channels desensitized in the presence of micromolar concentrations of acetylcholine. S-type channels desensitized less rapidly and less completely than did T-type channels. 6. Desensitized channels of both types recovered and produced bursts of activity, then went silent again. During a burst, channels did not appear to change type. 7. The activation of channels of either type was not correlated with activity in channels of the other type. 8. The open-duration distribution of S-type channels required two exponential components to be well fitted, with time constants in the range of 1-2 ms and 3-10 ms. In contrast, the open-duration distribution of T-type channels was a single exponential with a time constant similar in magnitude to the slower S-type component. 9. Desensitization-resistant S-type acetylcholine receptor channels could allow slow muscle end-plates to retain their sensitivity to acetylcholine during periods of heavy use. Under non-desensitizing conditions, differences in the decay properties of slow fibre end-plate currents compared to those in twitch fibres can be explained by the activation kinetics of S-type channels.

Biophysical and pharmacological properties of cloned GABAA receptor subunits expressed in Xenopus oocytes.

Biochemical and immunological studies indicate that the GABAA receptor contains at least two types of subunit. Here we report that coexpression of two GABAA receptor subunit clones (alpha and beta) in Xenopus oocytes yields receptors with many biophysical properties of native GABAA receptors. These include ion selectivity, multiple single-channel conductance states, voltage-dependent gating and rectification, and complex desensitization kinetics. Furthermore, the receptors are competitively inhibited by bicuculline and display the expected allosteric and agonist effects of the barbiturate pentobarbital. The expressed receptors, however, appear to be activated by one molecule of GABA instead of two and fail to show potentiation by benzodiazepines. This implies that an additional factor(s) or subunit(s) is required for the reconstitution of a fully functional GABAA receptor.

Single subunits of the GABAA receptor form ion channels with properties of the native receptor.

The alpha and beta subunits of the gamma-aminobutyric acidA (GABAA) receptor were expressed individually in Xenopus oocytes by injection of RNA synthesized from their cloned DNAs. GABA-sensitive chloride channels were detected several days after injection with any one of three different alpha RNAs (alpha 1, alpha 2, and alpha 3) or with beta RNA. The channels induced by each of the alpha-subunit RNAs were indistinguishable, they had multiple conductance levels (10, 19, 28, and 42 picosiemens), and their activity was potentiated by pentobarbital and inhibited by picrotoxin. The beta channels usually expressed poorly but showed similar single channel conductance levels (10, 18, 27, and 40 picosiemens), potentiation by pentobarbital and inhibition by picrotoxin. The finding that both alpha and beta subunits, examined separately, form GABA-sensitive ion channels with permeation properties and regulatory sites characteristic of the native receptor suggests that the amino acid sequences that confer these properties are within the homologous domains shared by the subunits.