Relative roles of protein kinase A and protein kinase C in modulation of transient receptor potential vanilloid type 1 receptor responsiveness in rat sensory neurons in vitro and peripheral nociceptors in vivo

The function of the transient receptor potential vanilloid type 1 capsaicin receptor is subject to modulation by phosphorylation catalyzed by various enzymes including protein kinase C and cAMP-dependent protein kinase. The aim of this study was to compare the significance of the basal and stimulated activity of protein kinase C and cAMP-dependent protein kinase in transient receptor potential vanilloid type 1 receptor responsiveness in the rat in vitro by measurement of the intracellular calcium concentration in cultured trigeminal ganglion neurons and in vivo by determination of the behavioral noxious heat threshold. KT5720, a selective inhibitor of cAMP-dependent protein kinase, reduced the calcium transients induced by capsaicin or the other, much more potent transient receptor potential vanilloid type 1 receptor agonist resiniferatoxin in trigeminal sensory neurons and diminished the drop of the noxious heat threshold (heat allodynia) evoked by intraplantar resiniferatoxin injection. Chelerythrine chloride, a selective inhibitor of protein kinase C, failed to alter either of these responses, although it inhibited the effect of phorbol 12-myristate 13-acetate in the in vitro assay. Staurosporine, a rather nonselective protein kinase inhibitor, failed to reduce the capsaicin- and resiniferatoxin-induced calcium transients but inhibited the resiniferatoxin-evoked heat allodynia. Dibutyryl-cAMP and phorbol 12-myristate 13-acetate, activator(s) of cAMP-dependent protein kinase and protein kinase C, respectively, enhanced the effect of capsaicin in the calcium uptake assay while forskolin, an activator of adenylyl cyclase, augmented that of resiniferatoxin in the heat allodynia model. None of the protein kinase inhibitors or activators altered the calcium transients evoked by high potassium, a nonspecific depolarizing stimulus. It is concluded that basal activity of cAMP-dependent protein kinase, unlike protein kinase C, is involved in the maintenance of transient receptor potential vanilloid type 1 receptor function in somata of trigeminal sensory neurons but stimulation of either cAMP-dependent protein kinase or protein kinase C above the resting level can lead to an enhanced transient receptor potential vanilloid type 1 receptor responsiveness. Similar mechanisms are likely to operate in vivo in peripheral terminals of nociceptive dorsal root ganglion neurons.     

Odorant Responsiveness of Squid Olfactory Receptor Neurons

In the olfactory organ of the squid, Lolliguncula brevis there are five morphological types of olfactory receptor neurons (ORNs). Previous work to characterize odor sensitivity of squid ORNs was performed on only two of the five types in dissociated primary cell cultures. Here, we sought to establish the odorant responsiveness of all five types. We exposed live squid or intact olfactory organs to excitatory odors plus the activity marker, agmatine (AGB), an arginine derivative that enters cells through nonselective cation channels. An antibody against AGB was used to identify odorant‐activated neurons. We were able to determine the ORN types of AGB‐labeled cells based on their location in the epithelium, morphology and immunolabeling by a set of metabolites: arginine, aspartate, glutamate, glycine, and glutathione. Of 389 neurons identified from metabolite‐labeled tissue, 3% were type 1, 32% type 2, 33% type 3, 15% type 4, and 17% type 5. Each ORN type had different odorant specificity with type 3 cells showing the highest percentages of odorant‐stimulated AGB labeling. Type 1 cells were rare and none of the identified type 1 cells responded to the tested odorants, which included glutamate, alanine and AGB. Glutamate is a behaviorally attractive odorant and elicited AGB labeling in types 2 and 3. Glutamate‐activated AGB labeling was significantly reduced in the presence of the adenylate cyclase inhibitor, SQ22536 (80 μM). These data suggest that the five ORN types differ in their relative abundance and odor responsiveness and that the adenylate cyclase pathway is involved in squid olfactory transduction. Anat Rec, 291:763‐774, 2008. © 2008 Wiley‐Liss, Inc.     

Trial-by-trial discrimination of three enantiomer pairs by neural ensembles in mammalian olfactory bulb

Populations of output neurons in the mammalian olfactory bulb (OB) exhibit distinct, widespread spatial and temporal activation patterns when stimulated with odorants. However, questions remain as to how ensembles of mitral/tufted (M/T) neurons in the mammalian OB represent odorant information. In this report, the single-trial encoding limits of random ensembles of putative single- and multiunit M/T cells in the anesthetized rat OB during presentations of enantiomers of limonene, carvone, and 2-butanol are investigated using simultaneous multielectrode recording techniques. The results of these experiments are: the individual constituents of our recorded ensembles broadly represent information about the presented odorants, the ensemble single-trial response of small spatially distributed populations of M/T neurons can readily discriminate between six different odorants, and the most consistent odorant discrimination is attained when the ensemble consists of all available units and their responses are integrated over an entire breathing cycle. These results suggest that small differences in spike counts among the ensemble members become significant when taken within the context of the entire ensemble. This may explain how ensembles of broadly tuned OB neurons contribute to olfactory perception and may explain how small numbers of individual units receiving input from distinct olfactory receptor neurons can be combined to form a robust representation of odorants.     

Voltage‐dependent anion channel (VDAC‐1) is required for olfactory sensing in Caenorhabditis elegans

The Ras–MAP kinase signaling pathway plays important roles for the olfactory reception in olfactory neurons in Caenorhabditis elegans. However, given the absence of phosphorylation targets of MAPK in the olfactory neurons, the mechanism by which this pathway regulates olfactory function is unknown. Here, we used proteomic screening to identify the mitochondrial voltage‐dependent anion channel VDAC‐1 as a candidate target molecule of MAPK in the olfactory system of C. elegans. We found that Amphid Wing “C” (AWC) olfactory neuron‐specific knockdown of vdac‐1 caused severe defects in chemotaxis toward AWC‐sensed odorants. We generated a new vdac‐1 mutant using the CRISPR‐Cas9 system, with this mutant also showing decreased chemotaxis toward odorants. This defect was rescued by AWC‐specific expression of vdac‐1, indicating that functions of VDAC‐1 in AWC neurons are essential for normal olfactory reception in C. elegans. We observed that AWC‐specific RNAi of vdac‐1 reduced AWC calcium responses to odorant stimuli and caused a decrease in the quantity of mitochondria in the sensory cilia. Behavioral abnormalities in vdac‐1 knockdown animals might therefore be due to reduction of AWC response, which might be caused by loss of mitochondria in the cilia. Here, we showed that the function of VDAC‐1 is regulated by phosphorylation and identified Thr175 as the potential phosphorylation site of MAP kinase.     

Integration of CO2 and odorant signals in the mouse olfactory bulb

Carbon dioxide (CO₂) is an important environmental cue for many animal species. In both vertebrates and invertebrates, CO₂ is detected by a specialized subset of olfactory sensory neurons (OSNs) and mediates several stereotypical behaviors. It remains unknown how CO₂ cues are integrated with other olfactory signals in the mammalian olfactory bulb, the first stage of central olfactory processing. By recording from the mouse olfactory bulb in vivo, we found that CO₂-activating neurons also respond selectively to odorants, many of which are putative mouse pheromones and natural odorants. In addition, many odorant-responsive bulbar neurons are inhibited by CO₂. For a substantial number of CO₂-activating neurons, binary mixtures of CO₂ and a specific odorant produce responses that are distinct from those evoked by either CO₂ or the odorant alone. In addition, for a substantial number of CO₂-inhibiting neurons, CO₂ addition can completely block the action potential firing of the cells to the odorants. These results indicate strong interaction between CO₂ signals and odorant signals in the olfactory bulb, suggesting important roles for the integration of these two signals in CO₂-mediated behavioral responses.     

Neural activity at the human olfactory epithelium reflects olfactory perception

Organization of receptive surfaces reflects primary axes of perception. In vision, retinal coordinates reflect spatial coordinates. In audition, cochlear coordinates reflect tonal coordinates. However, the rules underlying the organization of the olfactory receptive surface are unknown. To test the hypothesis that organization of the olfactory epithelium reflects olfactory perception, we inserted an electrode into the human olfactory epithelium to directly measure odorant-induced evoked responses. We found that pairwise differences in odorant pleasantness predicted pairwise differences in response magnitude; that is, a location that responded maximally to a pleasant odorant was likely to respond strongly to other pleasant odorants, and a location that responded maximally to an unpleasant odorant was likely to respond strongly to other unpleasant odorants. Moreover, the extent of an individual's perceptual span predicted their span in evoked response. This suggests that, similarly to receptor surfaces for vision and audition, organization of the olfactory receptor surface reflects key axes of perception.     

Interglomerular center-surround inhibition shapes odorant-evoked input to the mouse olfactory bulb in vivo

Mouse olfactory receptor proteins have relatively broad odorant tuning profiles, so single odorants typically activate a substantial subset of glomeruli in the main olfactory bulb, resulting in stereotyped odorant- and concentration-dependent glomerular input maps. One of the functions of the olfactory bulb may be to reduce the extent of this rather widespread activation before transmitting the information to higher olfactory centers. Two circuits have been studied in vitro that could perform center-surround inhibition in the olfactory bulb, one circuit acting between glomeruli, the other through the classical reciprocal synapses between the lateral dendrites of mitral cells and the dendrites of granule cells. One unanswered question from these in vitro measurements was how these circuits would affect the response to odorants in vivo. We made measurements of the odorant-evoked increase in calcium concentration in the olfactory receptor neuron terminals in the anesthetized mouse to evaluate the role of presynaptic inhibition in reshaping the input to the olfactory bulb. We compared the glomerular responses in 2- to 4-wk-old mice before and after suppressing presynaptic inhibition onto the receptor neuron terminals with the GABAB antagonist, CGP46381. We find that the input maps are modified by an apparent center-surround inhibition: strongly activated glomeruli appear to suppress the release from receptor neurons terminating in surrounding glomeruli. This form of lateral inhibition has the effect of increasing the contrast of the sensory input map.     

Discrimination among odorants by single neurons of the rat olfactory bulb

1. Intracellular and extracellular recordings were made from rat olfactory bulb mitral and tufted cells during odor stimulation and during electrical stimulation of the olfactory nerve. Neurons were identified by horseradish peroxidase injections and/or antidromic activation. The presentation of multiple concentrations of at least one odorant in a cyclic artificial sniff paradigm, as reported previously (10), allowed the study of odor responses. This approach was extended to multiple odorants to compare their concentration-response profiles. This procedure avoids the problems of interpretation resulting from nonequivalence of the effective concentrations of different odorants used as stimuli that have characterized previous studies of odor quality effects. Comparisons of intracellular events and responses to electrical stimulation with the odor-induced spike train activity allow us to begin to delineate the local circuitry involved in generating odor-induced responses. 2. The concentration-response profiles of the 72 cells in the present study are comparable to those previously reported for output neurons of the olfactory bulb, showing ordered changes in the temporal patterning of spike activity with step changes in odor concentration. However, eight of the neurons exhibited inhibitory responses to lower concentrations, but excitation, at similar latency, to higher concentrations of the same odorant. These data emphasize that to study pattern changes induced by changing odor quality the influence of stimulus intensity must also be carefully examined. The data also provide evidence that the temporal pattern evoked by an odorant is probably not in itself the code for odor quality recognition. 3. Complete concentration-response profiles, including subthreshold concentrations, to more than one odorant show that, although responses to the different odorant can evolve systematically with concentration, the responses to different odorants can evolve through very different patterns. For example, in some cells, the response patterns to different odors were complementary in form. These results demonstrate that the patterned responses of olfactory bulb neurons can reflect changes in odor quality as well as intensity. 4. Intracellular recording was employed to compare the temporal patterning of spikes during odor stimulation with membrane potential changes. In some cases, the spike pattern was closely correlated with apparent postsynaptic potentials. However, there were several clear exceptions. In five cells, a prominent hyperpolarization, seen in the first sniff of a series of 10 consecutive sniffs, was associated with pauses in spike activity. In the following     

Mitral and tufted cells differ in the decoding manner of odor maps in the rat olfactory bulb

Mitral and tufted cells in the mammalian olfactory bulb are principal neurons, each type having distinct projection pattern of their dendrites and axons. The morphological difference suggests that mitral and tufted cells are functionally distinct and may process different aspects of olfactory information. To examine this possibility, we recorded odorant-evoked spike responses from mitral and middle tufted cells in the aliphatic acid- and aldehyde-responsive cluster at the dorsomedial part of the rat olfactory bulb. Homologous series of aliphatic acids and aldehydes were used for odorant stimulation. In response to adequate odorants, mitral cells showed spike responses with relatively low firing rates, whereas middle tufted cells responded with higher firing rates. Examination of the molecular receptive range (MRR) indicated that most mitral cells exhibited a robust inhibitory MRR, whereas a majority of middle tufted cells showed no or only a weak inhibitory MRR. In addition, structurally different odorants that activated neighboring clusters inhibited the spike activity of mitral cells, whereas they caused no or only a weak inhibition in the middle tufted cells. Furthermore, responses of mitral cells to an adequate excitatory odorant were greatly inhibited by mixing the odorant with other odorants that activated neighboring glomeruli. In contrast, odorants that activated neighboring glomeruli did not significantly inhibit the responses of middle tufted cells to the adequate excitatory odorant. These results indicate a clear difference between mitral and middle tufted cells in the manner of decoding the glomerular odor maps.     

Pro- and anti-nociceptive effects of corticotropin-releasing factor (CRF) in central amygdala neurons are mediated through different receptors

Corticotropin-releasing factor (CRF) is not only a stress hormone but also acts as a neuromodulator outside the hypothalamic-pituitary-adrenocortical axis, playing an important role in anxiety, depression, and pain modulation. The underlying mechanisms remain to be determined. A major site of extra-hypothalamic expression of CRF and its receptors is the amygdala, a key player in affect-related disorders such as anxiety. The latero-capsular division of the central nucleus of the amygdala (CeLC) is also important for pain modulation and pain affect. This study analyzed the effects of CRF on nociceptive processing in CeLC neurons and the contribution of CRF1 and CRF2 receptors and protein kinases A and C. Extracellular single-unit recordings were made from CeLC neurons in anesthetized adult rats. All neurons responded more strongly to noxious than innocuous mechanical stimulation of the knee. Evoked responses and background activity were measured before and during administration of CRF into the CeLC by microdialysis. CRF was administered alone or together with receptor antagonists or protein kinase inhibitors. CRF (0.01-1 microM; concentrations in microdialysis probe; 15 min) facilitated the evoked responses more strongly than background activity; a higher concentration (10 microM) had inhibitory effects. Facilitation by CRF (0.1 microM) was reversed by a selective CRF1 receptor antagonist (NBI27914, 10 microM) but not a CRF2 receptor antagonist (astressin-2B, 100 microM) and by a protein kinase A (PKA) inhibitor (KT5720, 100 microM) but not a protein kinase C inhibitor (GF109203X, 100 microM). Inhibitory effects of CRF (10 microM) were reversed by astressin-2B. These data suggest that CRF has dual effects on amygdala neurons: CRF1 receptor-mediated PKA-dependent facilitation and CRF2 receptor-mediated inhibition.     

Respiratory-phase-related coding of olfactory information in the olfactory bulb of awake freely-breathing rabbits

The "across-neuron pattern" theory of olfactory information coding states that odorants are represented by spatial patterns of activity produced across-neurons in the olfactory bulbs. The present study analyzes the different response patterns encoding olfactory information in both the inspiratory and expiratory phases of the respiratory cycles of awake freely-breathing rabbits. We recorded the single-unit responses of 31 neurons to 5 different odorants, 3 of which were repeatedly delivered 5 times each. These responses were characterized by the change in their mean firing activity during the inspiratory and expiratory phases of the respiratory cycles respectively. Their processing using principal component analyses revealed that both the inspiration- and the expiration-related across-neuron profiles of responses contained information appropriate to the specification of each odorant. It was therefore concluded that there was a dynamic representation of odorants in the olfactory bulb of awake freely-breathing animals. This alternate representation of odorants by two profiles and its physiological significance are discussed.     

Amino-acid changes acquired during evolution by olfactory receptor 912-93 modify the specificity of odorant recognition

The sense of smell in mammals can perceive and discriminate a wide variety of volatile odorants. Odorants bind to specific olfactory receptors (ORs) to initiate an action potential that transduces olfactory information to the olfactory cortex. We previously identified the structural motifs of odorant molecules (aliphatic 2- or 3-ketones) required to activate mouse OR912-93 by detection of the odorant response using calcium measurement in transfected cells. In order to study changes in the specificity of this receptor that might have occurred during evolution, we cloned the orthologous genes from six primate species and pig and assayed the encoded receptors for responses to odorants. Primate OR912-93 orthologs share 88-97% sequence identity. All the receptors responded to 2- and 3-heptanone except the squirrel-monkey OR, which responded only to 3-heptanone, and the human and orangutan ORs, which were not functional. Directed mutagenesis allowed us to convert the squirrel-monkey response to that of the other functional 912-93 ORs by substituting three amino acids in the second extracellular loop. Orangutan and human 912-93 ORs regained function after restoration of the arginine residue in the DRY motif required for G-protein activation. However, the human receptor was constitutively activated in the absence of ligand stimulation. Using natural mutants of the OR912-93 receptor, we provide evidence that squirrel-monkeys evolved towards a restriction of the specificity of this receptor and therefore that slight alterations in the sequence of a receptor can induce subtle changes in recognition specificity.     

Olfactory cortical adaptation facilitates detection of odors against background

Detection and discrimination of odors generally, if not always, occurs against an odorous background. On any given inhalation, olfactory receptor neurons will be activated by features of both the target odorant and features of background stimuli. To identify a target odorant against a background therefore, the olfactory system must be capable of grouping a subset of features into an odor object distinct from the background. Our previous work has suggested that rapid homosynaptic depression of afferents to the anterior piriform cortex (aPCX) contributes to both cortical odor adaptation to prolonged stimulation and habituation of simple odor-evoked behaviors. We hypothesize here that this process may also contribute to figure-ground separation of a target odorant from background stimulation. Single-unit recordings were made from both mitral/tufted cells and aPCX neurons in urethan-anesthetized rats and mice. Single-unit responses to odorant stimuli and their binary mixtures were determined. One of the odorants was randomly selected as the background and presented for 50 s. Forty seconds after the onset of the background stimulus, the second target odorant was presented, producing a binary mixture. The results suggest that mitral/tufted cells continue to respond to the background odorant and, when the target odorant is presented, had response magnitudes similar to that evoked by the binary mixture. In contrast, aPCX neurons filter out the background stimulus while maintaining responses to the target stimulus. Thus the aPCX acts as a filter driven most strongly by changing stimuli, providing a potential mechanism for olfactory figure-ground separation and selective reading of olfactory bulb output.     

Phosphorylation of extracellular signal-related protein kinase is required for rapid facilitation of heat-induced currents in rat dorsal root ganglion neurons

A subgroup of dorsal root ganglion (DRG) neurons responds to noxious heat with an influx of cations carried by specific ion channels such as the transient receptor potential channel of the vanilloid receptor type, subtype 1 (TRPV1). Application of capsaicin induces a reversible facilitation of these currents. This facilitation could be an interaction of two agonists at their common receptor or be caused by an influx of calcium ions into the cell. Calcium influx into the cell can activate protein kinases such as the extracellular signal-related protein kinase (ERK) pathway. This study explored the kinetics, calcium-dependency and intracellular signals following application of capsaicin and leading to facilitation of heat-induced currents (Iheat) in rat DRG neurons. Application of 0.5 microM capsaicin caused a 2.65-fold increase of Iheat within 2 s, which was significantly correlated to a small capsaicin-induced current. Intracellular application of 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA), a fast calcium chelator, did not change capsaicin-induced currents or Iheat itself, but inhibited facilitation of Iheat by capsaicin. ERK is activated by calcium influx and membrane depolarization via the mitogen-activated protein kinase/extracellular signal-related protein kinase kinase (MEK). Application of the MEK inhibitor U0126 also inhibited facilitation of Iheat by capsaicin. We conclude that the MEK/ERK cascade is an intracellular signaling pathway playing a vital role in the regulation of nociceptive neurons' sensitivity. The very fast kinetics (less than two seconds) are only explainable with a membrane-attached or at least membrane-near localization of these kinases.     

Serotonin Modulates Olfactory Processing in the Antennal Lobe of Drosophila

Sensory systems must be able to extract features of environmental cues within the context of the different physiological states of the organism and often temper their activity in a state-dependent manner via the process of neuromodulation. We examined the effects of the neuromodulator serotonin on a well-characterized sensory circuit, the antennal lobe of Drosophila melanogaster, using two-photon microscopy and the genetically expressed calcium indicator, G-CaMP. Serotonin enhances sensitivity of the antennal lobe output projection neurons in an odor-specific manner. For odorants that sparsely activate the antennal lobe, serotonin enhances projection neuron responses and causes an offset of the projection neuron tuning curve, most likely by increasing projection neuron sensitivity. However, for an odorant that evokes a broad activation pattern, serotonin enhances projection neuron responses in some, but not all, glomeruli. Further, serotonin enhances the responses of inhibitory local interneurons, resulting in a reduction of neurotransmitter release from the olfactory sensory neurons via GABA_B receptor-dependent presynaptic inhibition, which may be a mechanism underlying the odorant-specific modulation of projection neuron responses. Our data suggest that the complexity of serotonin modulation in the antennal lobe accommodates coding stability in a glomerular pattern and flexible projection neuron sensitivity under different physiological conditions.     

Odorant modulation of neuronal activity and local field potential in sensory-deprived olfactory bulb

Neuronal discharge and local field potential (LFP) oscillations in the olfactory bulb (OB) are modulated by odorant stimulation. The LFP oscillations have been proposed as the mechanism that facilitates synchronization of OB output neurons and the representation of similar odorants. Gamma LFP oscillations depend on the OB inhibitory network and early sensory deprivation modifies this inhibitory network. However, little is known about the LFP oscillations and neuronal discharge in the deprived OB. We examined the mitral/tufted (MT) cells' oscillatory activity and LFP oscillations in both sensory-deprived and normal OBs in urethane anesthetized rats. We found that MT cells in deprived and normal OBs have similar basal mean firing rate; 44% of the recorded cells in deprived OB and only 8% of the cells in normal OB showed firing rate modulation by odorants, both exhibiting a similar ratio of excitatory to inhibitory responses. A fraction of MT cells exhibited oscillatory discharge centered on gamma (60–70 Hz) and beta (20 Hz) frequencies, although this feature was not consistently dependent on odorant stimulation. Odorants decreased the LFP oscillatory power in the gamma band (35–90 Hz) and increased the power in the beta band (12–30 Hz). The modulation of LFP oscillations by odorants was also predominant in the deprived (53%) compared to the normal OB (17%). In contrast, a higher fraction of MT cells' discharge was locked to the gamma LFP cycle in the normal OB. These results suggest that early unilateral olfactory deprivation increases the OB sensitivity to odorants and reduce the temporal synchrony between unitary activity and gamma LFP oscillations without altering the basal neuronal discharge.     

Alteration of olfactory perceptual learning and its cellular basis in aged mice

Olfactory perceptual learning reflects an ongoing process by which animals learn to discriminate odorants thanks to repeated stimulations by these odorants. Adult neurogenesis is required for this learning to occur in young adults. The experiments reported here showed that olfactory perceptual learning is impaired with aging and that this impairment is associated with a reduction of neurogenesis and a decrease in granule cell responsiveness to the learned odorant in the olfactory bulb. Interestingly, we showed that the pharmacological stimulation of the noradrenergic system using dexefaroxan mimics olfactory perceptual learning in old mice, which is accompanied by an increase of granule cell responsiveness in response to the learned odorant without any improvement in neurogenesis. We provide the first published evidence that, in contrast to young adult mice, the improvement of olfactory performances in old mice is independent of the overall level of neurogenesis. In addition, restoring behavioral performances in old mice by stimulation of the noradrenergic system underlies the importance of this neuromodulatory system in regulating bulbar network plasticity.     

Effects of odor stimulation on antidromic spikes in olfactory sensory neurons

Spikes were evoked in rat olfactory sensory neuron (OSN) populations by electrical stimulation of the olfactory bulb nerve layer in pentobarbital anesthetized rats. The latencies and recording positions for these compound spikes showed that they originated in olfactory epithelium. Dual simultaneous recordings indicated conduction velocities in the C-fiber range, around 0.5 m/s. These spikes are concluded to arise from antidromically activated olfactory sensory neurons. Electrical stimulation at 5 Hz was used to track changes in the size and latency of the antidromic compound population spike during the odor response. Strong odorant stimuli suppressed the spike size and prolonged its latency. The latency was prolonged throughout long odor stimuli, indicating continued activation of olfactory receptor neuron axons. The amounts of spike suppression and latency change were strongly correlated with the electroolfactogram (EOG) peak size evoked at the same site across odorants and across stimulus intensities. We conclude that the curve of antidromic spike suppression gives a reasonable representation of spiking activity in olfactory sensory neurons driven by odorants and that the correlation of peak spike suppression with the peak EOG shows the accuracy of the EOG as an estimate of intracellular potential in the population of olfactory sensory neurons. In addition, these results have important implications about traffic in olfactory nerve bundles. We did not observe multiple peaks corresponding to stimulated and unstimulated receptor neurons. This suggests synchronization of spikes in olfactory nerve, perhaps by ephaptic interactions. The long-lasting effect on spike latency shows that action potentials continue in the nerve throughout the duration of an odor stimulus in spite of many reports of depolarization block in olfactory receptor neuron cell bodies. Finally, strong odor stimulation caused almost complete block of antidromic spikes. This indicates that a very large proportion of olfactory axons was activated by single strong odor stimuli.     

Gonadotropin releasing hormone (GnRH) modulates odorant responses in the peripheral olfactory system of axolotls

Peripheral signal modulation plays an important role in sensory processing. Activity in the vertebrate olfactory epithelium may be modulated by peptides released from the terminal nerve, such as gonadotropin releasing hormone (GnRH). Here, we demonstrate that GnRH modulates odorant responses in aquatic salamanders (axolotls, Ambystoma mexicanum). We recorded electrical field potentials (electro-olfactograms, or EOGs) in response to stimulation with four different amino acid odorants, L-lysine, L-methionine, L-cysteine, and L-glutamic acid. EOG responses were recorded from the main olfactory epithelium before, during, and after application of 10 microM GnRH. This protocol was repeated for a total of three trials with 60-80 min between trials. The effect of GnRH on EOG responses was broadly similar across odorants and across trials. In general, EOG responses were reduced to 79% of the initial magnitude during application of GnRH; in some trials in which glutamic acid served as the odorant, EOG responses were enhanced during the wash period. Although the 4-min inter-stimulus interval did not lead to adaptation of EOG responses during the first trial, we frequently observed evidence of adaptation during the second and third trials. In addition, we found that lower concentrations of GnRH produced a smaller effect. These results demonstrate that GnRH can modulate odorant responses in the peripheral olfactory system.     

A Toll-interleukin 1 repeat protein at the synapse specifies asymmetric odorant receptor expression via ASK1 MAPKKK signaling

A stochastic lateral signaling interaction between two developing Caenorhabditis elegans AWC olfactory neurons causes them to take on asymmetric patterns of odorant receptor expression, called AWC(OFF) and AWC(ON). Here we show that the AWC lateral signaling gene tir-1 (previously known as nsy-2) encodes a conserved post-synaptic protein that specifies the choice between AWC(OFF) and AWC(ON). Genetic evidence suggests that tir-1 acts downstream of a voltage-gated calcium channel and CaMKII (UNC-43) to regulate AWC asymmetry via the NSY-1(ASK1) p38/JNK MAP (mitogen-activated protein) kinase cascade. TIR-1 localizes NSY-1 to post-synaptic regions of AWC, and TIR-1 binds UNC-43, suggesting that it assembles a synaptic signaling complex that regulates odorant receptor expression. Temperature-shift experiments indicate that tir-1 affects AWC during a critical period late in embryogenesis, near the time of AWC synapse formation. TIR-1 is a multidomain protein with a TIR (Toll-interleukin-1 receptor) domain that activates signaling, SAM repeats that mediate localization to post-synaptic regions of axons, and an N-terminal inhibitory domain. TIR-1 and other TIR proteins are implicated in vertebrate and invertebrate innate immunity, as are NSY-1/ASK1 kinases, so this pathway may also have a conserved function in immune signaling.