The morphology and physiology of the granule cells in the rabbit olfactory bulb revealed by intracellular recording and HRP injection

Regulation of granule cell excitability by a low-threshold calcium spike in turtle olfactory bulb

Granule cells excitability in the turtle olfactory bulb was analyzed using whole cell recordings in current- and voltage-clamp mode. Low-threshold spikes (LTSs) were evoked at potentials that are subthreshold for Na spikes in normal medium. The LTSs were evoked from rest, but hyperpolarization of the cell usually increased their amplitude so that they more easily boosted Na spike initiation. The LTS persisted in the presence of TTX but was antagonized by blockers of T-type calcium channels. The voltage dependence, kinetics, and inactivation properties of the LTS were characteristic of a low-threshold calcium spike. The threshold of the LTS was slightly above the resting potential but well below the Na spike threshold, and the LTS was often evoked in isolation in normal medium. Tetraethylammonium (TEA) and 4-aminopyridine (4-AP) had only minimal effects on the LTS but revealed the presence of a high-threshold Ca2+ spike (HTS), which was antagonized by Cd2+. The LTS displayed paired-pulse attenuation, with a timescale for recovery from inactivation of about 2 s at resting membrane potential. The LTS strongly boosted Na spike initiation; with repetitive stimulation, the long recovery of the LTS governed Na spike initiation. Thus the olfactory granule cells possess an LTS, with intrinsic kinetics that contribute to sub- and suprathreshold responses on a timescale of seconds. This adds a new mechanism to the early processing of olfactory input.

Contribution of a calcium-activated non-specific conductance to NMDA receptor-mediated synaptic potentials in granule cells of the frog olfactory bulb

We studied granule cells (GCs) in the intact frog olfactory bulb (OB) by combining whole-cell recordings and functional two-photon Ca(2+) imaging in an in vitro nose-brain preparation. GCs are local interneurones that shape OB output via distributed dendrodendritic inhibition of OB projection neurones, the mitral-tufted cells (MTCs). In contrast to MTCs, GCs exhibited a Ca(2+)-activated non-specific cation conductance (I(CAN)) that could be evoked through strong synaptic stimulation or suprathreshold current injection. Photolysis of the caged Ca(2+) chelator o-nitrophenol-EGTA resulted in activation of an inward current with a reversal potential within the range -20 to +10 mV. I(CAN) in GCs was suppressed by the intracellular Ca(2+) chelator BAPTA (0.5-5.0 mM), but not by EGTA (up to 5 mM). The current persisted in whole-cell recordings for up to 1.5 h post-breakthrough, was observed during perforated-patch recordings and was independent of ionotropic glutamate and GABA(A) receptor activity. In current-clamp mode, GC responses to synaptic stimulation consisted of an initial AMPA-mediated conductance followed by a late-phase APV-sensitive plateau (100-500 ms). BAPTA-mediated suppression of I(CAN) resulted in a selective reduction of the late component of the evoked synaptic potential, consistent with a positive feedback relationship between NMDA receptor (NMDAR) current and I(CAN). I(CAN) requires Ca(2+) influx either through voltage-gated Ca(2+) channels or possibly NMDARs, both of which have a high threshold for activation in GCs, predicting a functional role for this current in the selective enhancement of strong synaptic inputs to GCs.

Potentiation of late components in olfactory bulb and piriform cortex requires activation of cortical association fibers

Previous research has demonstrated that repeated high-frequency stimulation of the granule cell layer of the olfactory bulb (OB) produces an enduring potentiation of late components (PLC) in potentials evoked in the OB and piriform cortex (PC), while leaving the monosynaptic EPSP produced by OB mitral cells in PC pyramidal cells unaltered. Two experiments were conducted using male Long-Evans rats with chronically implanted electrodes to assess the relative contribution to this potentiation of the two main fiber systems that interconnect the OB and PC: the lateral olfactory tract (LOT), which contains mitral cell axons that synapse on PC pyramidal cells, and the PC association fiber system, which consists of the axons of PC pyramidal cells that synapse on several cell populations within the PC and on granule cells in the OB. The results indicate that stimulation of PC association fibers is both necessary and sufficient to duplicate the pattern of potentiation seen following OB stimulation in previous experiments. LOT stimulation had no consistent effect, and coactivation of the LOT and PC association fibers was no more effective than activation of PC association fibers alone. Possible mechanisms underlying this effect are discussed, including (1) long-term potentiation (LTP) at synapses made by the axons of PC pyramidal cells on neurons in the OB and PC; and (2) repetitive firing in PC pyramidal cells due to regenerative excitation in a population of deep cells in the PC and endopiriform nucleus.

Abnormal synaptic transmission in the olfactory bulb of Fyn-kinase-deficient mice

We studied synaptic transmission in the granule cells in the olfactory bulb of the homozygous Fyn (a nonreceptor type tyrosine kinase)-deficient (fynz/fynz) and heterozygous Fyn-deficient (+/fynz) mice by using slice preparations from the olfactory bulb. Stimulation to the lateral olfactory tract and/or centrifugal fibers to the olfactory bulb evoked field excitatory postsynaptic potentials (fEPSPs) in the granule cells. In +/fynz mice, fEPSPs were augmented by bicuculline, a gamma-aminobutyric acid (GABAA) antagonist and picrotoxin, whereas fEPSPs in fynz/fynz mice were much less sensitive to bicuculline and picrotoxin. Application of D-2-amino-5-phosphonopentanoic acid had no effect but 6-cyano-7-nitroquinoxaline-2,3-dione produced almost complete block of fEPSPs in both +/fynz mice and fynz/fynz mice. (1S,3R)-1-aminocyclo-pentane-1.3-dicarboxylate, an agonist of metabotropic glutamate receptors caused a similar depression of fEPSPs in both +/fynz and fynz/fynz mice. In +/fynz mice tetanic stimulation to the lateral olfactory tract and/or centrifugal fibers induced N-methyl-D-aspartate (NMDA)-dependent long-term potentiation (LTP) of fEPSPs, whereas LTP was impaired in fynz/fynz mice. Our results demonstrate altered functions of GABAA and NMDA receptors in the olfactory system of Fyn-deficient mice.

Odor processing in the frog olfactory system

In the frog, unitary electrophysiological recordings have been extensively used to investigate odor processing along the olfactory pathways. From the responses of primary second-order neurons, neuroreceptor and mitral cells, odor stimuli could be classified in qualitative groups, revealing that neuronal discriminative mechanisms are partly based on the structure of odor molecule. In the olfactory bulb, thanks both to the anatomical convergence of primary afferences and intrinsic network properties, mitral cells have been demonstrated to gain in odor discrimination and detection power abilities. GABAergic bulbar interneurons were found to be involved in the control of mitral cell excitability, adjusting response thresholds and duration and promoting a progressive increase of burst discharges with stimulus concentration. Otherwise, dopamine was observed to shunt off mitral cell spontaneous activity without altering their odor responsivity properties. Dopamine was demonstrated to act through D2 receptors. Matching anatomical and electrophysiological data, D2 receptors are assumed to be localized on mitral cells. The frog olfactory cortex neurons, silent at rest, could be segregated in two functional groups basing on their odor response properties. The first group shared most intensity coding properties with mitral cells while showing a lower discriminative power, similar to that of neuroreceptor cells. By contrast, the second group provided only minimal intensity coding and, basing on its high discrimination power, was assumed to be mainly devoted to odor discrimination. Thus, along the olfactory pathways, intensity and quality odor parameters which are simultaneously encoded by a neuroreceptor or mitral cell, become specified by two distinct populations in the cortex.

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.

GABAergic and glutamatergic synaptic input to identified granule cells in salamander olfactory bulb

1. Whole-cell patch clamp recording techniques were applied to granule cells in an in vitro salamander olfactory bulb preparation to study their morphology, membrane properties and pharmacology of postsynaptic responses to electrical stimulation of either the olfactory nerve (ON) or medial olfactory tract (MOT). Optical recordings of the same preparations stained with the voltage-sensitive dye RH414 were also made. 2. Anatomical reconstructions of biocytin-filled granule cells showed that they extend widespread spine-bearing dendrites and an axon-like process that branched within the external plexiform layer. 3. ON or MOT stimulation evoked a long-lasting depolarization, usually generating only a single action potential, in granule cells studied under standard recording conditions. Bath application of bicuculline methiodide (BMI, a GABAA receptor antagonist, 20 or 25 microM) enhanced the spontaneous and electrically evoked excitatory drive to granule cells. 4. The electrically evoked synaptic responses consisted of both excitatory and inhibitory synaptic inputs. Using symmetrical Cl- conditions inside and outside the cell to enhance Cl- currents, spontaneous and electrically driven BMI-sensitive inhibitory postsynaptic currents (IPSCs) were revealed, indicating that granule cells receive GABAergic synaptic input. 5. Bath application of GABA (250 microM to 1 mM) shunted and hyperpolarized granule cells as observed directly from whole-cell recordings and indirectly from cell-attached patch single channel recordings. 6. Bath application of the glutamate receptor antagonists 6-cyano-2,3-dihydroxy-7-nitroquinoxaline (CNQX, 10 microM) and/or DL-2-amino-5-phosphonopentanoic acid (DL-AP5, 100 microM) showed that granule cell dendrodendritic EPSPs are shaped by both non-NMDA and NMDA receptors. 7. The time course and pharmacological sensitivity of both single granule cell responses and ensemble responses recorded optically in the deeper layers of the bulb correlated well. 8. It is concluded that salamander granule cells integrate several types of synaptic input, may have both dendritic and axonal output, and play a major role in generating voltage-sensitive dye signals in the olfactory bulb.

Electrophysiological and morphological properties of granule cells: patch-clamp recordings of newborn rabbit olfactory bulb slices

Granule cells were investigated by performing whole-cell patch-clamp recordings from thin slices of the olfactory bulb of newborn rabbits. Granule cells were intracellularly stained with Lucifer Yellow in their intact environment. During current-clamp measurements these neurones were characterized by their lack of action potentials upon depolarization. Evidence for a Ca2+ dependent K+ conductance was found. Two types of outward currents were identified in the whole cell mode during voltage clamp; a non-inactivating K+ current that shared some properties of the delayed rectifier K+ current and a non-inactivating K+ current were recorded. No fast inward current was registrated.

Heterogeneous characteristics of mitral cells in the rat olfactory bulb

The spontaneous firing activity of olfactory bulb mitral cells and their response to intrabulbar infusion of GABAA receptor antagonist bicuculline were studied in ovariectomized, urethane-anesthetized female rats. Mitral cells recorded in the absence of specific stimuli and nasal airflow displayed three distinct patterns of spontaneous firing: high-frequency bursts with relatively long silent periods; high-frequency bursts without accurately defined silent periods; continuous. Infusion of bicuculline (0.2 nmol) into the bulb yielded inconsistent results on spontaneous firing and its inhibition evoked by electrical stimulation of the lateral olfactory tract. Of 32 cells tested, the spontaneous firing rate increased for 24, decreased for 6, and was not altered for 2. Likewise, of 18 cells tested, the poststimulus inhibitory period shortened for 12, lengthened for 4, and not altered for 2. An increased dose (0.4 nmol) of bicuculline produced dose-response relationships simply without any reversal effect. These results suggest that the heterogeneity of mitral cells exists in the context of local interneuronal circuitry in the bulb.

Distribution of immunoreactivity for gamma-aminobutyric acid in the salamander olfactory bulb

Intrinsic neurons provide inhibitory synaptic input to mitral (and tufted) output cells within several laminae of the olfactory bulb. In rodents, the two main types of intrinsic neurons are granule and periglomerular cells, both of which contain gamma-aminobutyric acid (GABA). In the present study, immunocytochemical techniques were used to determine whether intrinsic neurons in the salamander olfactory bulb might also contain GABA. With the aid of two antisera to different GABA-conjugates, immunoreactivity for GABA was localized within the olfactory bulb laminae. In the glomerular layer, periglomerular cells, which were strongly immunoreactive, were concentrated in clusters along the border with the olfactory nerve layer. Dendrites of the cells encircled nearby glomeruli and were presumably a primary source of intraglomerular processes that were also stained. In the subglomerular region and external plexiform layer, relatively few immunoreactive cells were observed, most of which appeared to be periglomerular and tufted cell types with glomerular dendrites. Throughout the external plexiform and mitral cell layers, however, a dense matrix of spiny processes and puncta was stained, outlining large, unstained dendrites derived from the large, unstained cell bodies of mitral cells. The spiny processes and puncta appeared to be derived from granule cells, which were the most abundant immunoreactive cells in the bulb. Granule cell bodies filled the granule cell layer. In tissue fixed with 0.1-0.2% glutaraldehyde, staining in the olfactory bulb laminae was blocked by preadsorption of the two antisera with glutaraldehyde-conjugated GABA-bovine serum albumin. The staining therefore appeared to be specific for fixed GABA.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracellular responses of olfactory bulb granule cells to stimulating the horizontal diagonal band nucleus

The effects of centrifugal afferents on membrane potentials of identified granule cell layer using evoked field potential profiles, and trans-synaptic activation via antidromic stimulation of output cell axon collaterals. Intracellular recordings maintained for 4-30 min showed complex spontaneous spike discharges and allowed characterization of the cell's input resistance, and on some occasions its morphology following intracellular injection of Lucifer Yellow. Stimulation in the nucleus of the horizontal limb of the diagonal band, but not surrounding regions, produced hyperpolarizing responses in 13 of 27 cells in the granule cell layer; four of these were morphologically identified as granule cells of two types, in five the responses had reversal potentials more negative than the resting potential, and six were identified as granule cells by monosynaptic activation from output axon collaterals. A different set of three cells in the granule cell layer responded with depolarization. The results are consistent with the inhibition of tonic activity of granule cells by the nucleus of the horizontal limb of the diagonal band, leading to disinhibition of mitral and tufted cells via dendrodendritic synapses of granule cells on mitral/tufted cell secondary dendrites.

Characterization and anatomical distribution of selective long-term potentiation in the olfactory forebrain

High-frequency stimulation of the granule cell layer of the olfactory bulb (OB) has previously been shown to result in a form of long-term potentiation in the piriform cortex (PC) that is selective to late components of the potential evoked in the PC58. This phenomenon was explored in male Long-Evans rats with chronically implanted electrodes by recording potentials evoked in the OB and in various sites in the ipsilateral and contralateral PC before and after repeated high-frequency stimulation of the OB. Recordings at all sites exhibited a gradually developing potentiation that was selective to late components of the evoked potential. In the OB and ipsilateral PC this potentiation had an overt long-term component that lasted for days, and all sites exhibited a latent potentiation that enabled the reestablishment of substantial levels of potentiation by mild patterns of stimulation that had no effect in control animals. No potentiation of the population EPSP representing input from the lateral olfactory tract to the PC was seen. Available evidence concerning the neuronal elements activated by the stimulation and the neuronal events likely to underlie the potentiated components of the evoked potentials suggests that this potentiation may represent an enhancement of inhibitory interactions within the PC and between the PC and OB.

Effect of stimulating the nucleus of the horizontal limb of the diagonal band on single unit activity in the olfactory bulb

The effects of centrifugal afferents on single unit discharge in the main olfactory bulb were studied in anaesthetized rats. Recording with extracellular micropipettes revealed spontaneous firing in all bulb layers. Units were located to different laminae using evoked field-potential profiles and histological verification. Output neurons were identified by antidromic response to stimulation of the lateral olfactory tract. Single- or brief multiple-pulse stimulation in the nucleus of the horizontal limb of the diagonal band, but not in adjacent regions, facilitated 17 out of 27 mitral cells with no effect on 10, but inhibited 21 out of 33 granule cell layer units with no effect on 12. Of 13 presumed tufted cells, six were facilitated and the rest unaffected. In contrast, stimulation of olfactory cortex inhibited mitral cells and facilitated most granule layer cells. The results are consistent with an inhibition of tonic granule cell discharge by the horizontal diagonal band nucleus, with resultant disinhibition of mitral cells via the dendrodendritic synapses of granule cells on mitral cell secondary dendrites.

Golgi analyses of dendritic organization among denervated olfactory bulb granule cells

In the vertebrate olfactory bulb, the primary projection neurons, mitral and tufted cells, have reciprocal dendrodendritic synapses with respective subpopulations of anaxonic interneurons called granule cells. In the neurological murine mutant Purkinje Cell Degeneration (PCD), all mitral cells are lost during early adulthood. As a consequence, a subpopulation of granule cells is deprived of both afferent input and efferent targets. The effect of this event on the morphology and sublaminar distribution of granule cells was studied with light microscopic Golgi procedures in affected homozygous recessive PCD mutants and normal heterozygous littermate controls. In the control mice, a minimum of three subpopulations were identified predominantly on the basis of the topology of apical dendrites and their spinous processes within the external plexiform layer (EPL) of the olfactory bulb: type I had dendrites extending across the full width of the EPL and a homogeneous distribution of spines; type II had dendritic arbors confined to the deeper EPL; type III had apical dendrites that arborized extensively within the superficial EPL with no arbors or spines present in the deeper EPL. Prior studies suggest that type II cells form connections with mitral cells; type III cells form connections with tufted cells; and type I cells may integrate information from both populations of projection neurons. In the mutant PCD mice, the classification of subpopulations of granule cells proved difficult due to a compression of dendritic arbors within the EPL. Dendritic processes followed a more horizontal tangent relative to the radial orientation seen in control mice. The length of dendritic branches was reduced by approximately 20% with a corresponding decrease in the number of spines. The density of spines (#/1 micron of dendrite) was constant in both controls and mutants at approximately 0.21. Truncation of the dendrites in the PCD mutants appeared to occur at terminal portions because the number of dendritic bifurcations was equal in both groups of mice. The data are discussed in terms of subpopulations of granule cells in the mouse olfactory bulb, the sublaminar organization of olfactory bulb circuits, and the capacity for survival and plasticity in the reciprocal dendrodendritic circuits mediated by the granule cell spines.

Plasticity of dendrodendritic microcircuits following mitral cell loss in the olfactory bulb of the murine mutant Purkinje cell degeneration

Mitral cells of the olfactory bulb typically form reciprocal dendrodendritic synapses with anaxonic interneurons, granule cells, within a sublamina of the external plexiform layer. As a result of mitral cell loss in the murine mutant Purkinjie cell degeneration (PCD), subpopulations of these granule cells are denervated. The present report examines the capacity of these denervated interneurons to form new dendrodendritic microcircuits with a second population of olfactory bulb neurons, tufted cells. Quantitative ultrastructural assessments were made of the morphology and distribution of dendrodendritic circuits in the olfactory bulbs of normal heterozygous littermates and affected homozygous recessive PCD mice following mitral cell loss. There were no apparent morphological characteristics that distinguished the reciprocal synaptic connections formed by mitral cells from those formed by tufted cells. However, the segregation of mitral cell dendrodendritic circuits in the deep sublamina of the external plexiform layer (EPL) and tufted cell circuits in the superficial sublamina provided the basis for a comparative analysis of synaptic organization following mitral cell loss. Following mitral cell loss there was a significant reduction in the area occupied by characteristic mitral cell dendrites within the deep sublamina of the EPL. A slight but nonsignificant increase in the area occupied by granule cell spines was also observed. The number of synaptic appositions involving granule cells decreased slightly, the number involving tufted cells increased significantly in the mutant mice. This indicates that many granule cell spines survive denervation and establish new reciprocal dendrodendritic synapses at available sites on tufted cells. In both the control and mutant mice the ratios of symmetrical:asymmetrical dendrodendritic synapses closely approached 1. This demonstrates that not only do the denervated spines receive new afferent input from tufted cell dendrites, but they also establish the reciprocal efferent projection. These data are discussed in terms of the sublaminar organization of dendrodendritic microcircuits in the olfactory bulb and their capacity of plasticity and reorganization following pertubation.

Influence of stimulus intensity on the categories of single-unit responses recorded from olfactory bulb neurons in awake freely-breathing rabbits

This study analyzes the influence of increasing odor intensity on the single-unit activity of olfactory bulb neurons recorded in awake freely-breathing rabbits. Five odorants were delivered at four concentrations over a range of 2 log units. Inspiration-and expiration-related firing activities were analyzed separately to categorize the odor-evoked responses into excitation, suppression and no response. Increasing the odor concentration caused more neurons to show excitatory responses during the inspiratory phase of the respiratory cycle and/or suppressive responses during the expiratory phase. The highest concentration of each odor also caused several units to give suppressive responses during inspiratory phases or excitatory responses during expiratory phases. However, increasing odor concentration caused few responses (less than 2%) to change from excitation to suppression or vice versa. How these results relate to those from studies performed in anaesthetized animals and the implications of the results for olfactory coding will be discussed.

Distribution of local axon collaterals of mitral, displaced mitral, and tufted cells in the rabbit olfactory bulb

To determine the projection fields of intrabulbar axon collaterals, mitral, displaced mitral, and middle tufted cells in the rabbit olfactory bulb were stained by intracellular injection of HRP. The axon collaterals of mitral cells and displaced mitral cells were distributed exclusively within the granule cell layer (GrL). Those of middle tufted cells were distributed mostly in the GrL and on rare occasions in the mitral cell layer. None of these collaterals entered the external plexiform layer. Axon collaterals of mitral cells, emitted at the depths of the GrL, were distributed widely from the deep portion to the most superficial portion of the GrL. Collaterals of displaced mitral cells were also emitted in the deep part, but they tended to be distributed more superficially in the GrL than mitral cells. Collaterals of middle tufted cells were released and distributed superficially in the GrL. The axon collaterals of these principal cells typically extended for a longer distance than the secondary dendrites, and they sometimes formed bushlike terminal arborizations. The results indicate that the projection fields of the axon collaterals of principal cells are spatially separated from the dendritic projection fields. This suggests that the output of these principal cells through the collaterals has a functionally different role from the output through the dendrites. The observation that the three types of principal cells differ in the distribution pattern of their axon collaterals in the GrL suggests that there is a functional separation of the sublayers in the GrL.

Unit responses changing with behavioral outcome in the olfactory bulb of unrestrained rats

The unit activity of 16 neurons, including 12 likely mitral cells, was recorded in one olfactory bulb of 5 unrestrained rats, together with contralateral multiunit activity, and respiratory rhythm. The hungry animals were stimulated either by food odor (F) learned as a signal for one available food pellet, or by isoamyl acetate (IA), presented randomly. Eighty-four sequences, each with one stimulation, were analyzed to determine how the odors modified unit, multiunit and respiratory activities. The stimulation could change the variance and/or mean of the unit discharge and its correlation with the respiration phase or frequency or with multiunit activity. Besides the IA sequences, F+, F= and F-situations had to be distinguished, when the pellet was eaten spontaneously, accepted if presented at mouth or refused actively. The neuron responses were reproducible, in a given situation, but their occurrence within a series of identical stimuli was unpredictable from the controlled or observed events. The positive mitral responses were more probable in the F+ and F= than in the F-sequences; they were then associated with multiunit and respiratory activation. Response criteria and neuron typology are discussed. The functional involvements of neuron variability and modulation with internal state are considered.

Antidromic activation of spikes with bimodal and trimodal latencies in the olfactory bulb of rabbits

Spikes with bimodal and occasional trimodal latencies were recorded from neurons in the olfactory bulb of rabbits in response to lateral olfactory tract (LOT) stimulation at one site. Among neurons with bimodal spike latencies, two types have to be distinguished. In the case of type I neurons long-latency second-mode spikes were suppressed by short-latency first-mode spikes. Due to this suppression the long-latency second-mode spike could be investigated only, when its threshold was lower than that of the short-latency spike. In the case of type II neurons the long-latency second-mode spike was not suppressed. The collision test was applied to type I bimodal spikes. All short-latency first-mode and long-latency second-mode spikes were suppressed by spontaneous spikes. The suppression time indicated the likelihood of collision in most cases, but one could not entirely exclude the possibility, that short-latency first-mode spikes were suppressed due to refractoriness and long-latency second-mode spikes due to inhibition. To allow a more definite interpretation of collision a multiple collision test was applied, by stimulating axons at several LOT sites. A parallel rise of latency values and suppression time values was measured for 3 and more axonal spikes with different latencies, indicating collision and antidromic activation more definitely. Antidromically activated short-latency first-mode spikes were interpreted to be due to axonal stimulation and antidromically activated long-latency second-mode spikes to be due to axon collateral stimulation. No evidence for any postsynaptic activation of type I short-latency first-mode or long-latency second-mode spikes was gained. An indicator for collision of an antidromic spike with a spontaneous spike is the value collision time minus latency (c-l). The c-l values of axonal spikes ranged from 0.2 to 1.8 ms with a mean of 0.7 ms (n = 25), and c-l values of axon collateral spikes from 0.2 to 2.5 ms, with a mean of 1.1 ms (n = 13). The interpretation of c-l values is discussed. In the multiple collision test the c-l deviations from the lowest c-l value of each neuron ranged for axonal spikes between 0.0 and 0.7 ms (n = 25), with 38% not exceeding 0.1 ms and 81% not exceeding 0.4 ms. Spikes activated via axon collaterals had c-l deviations between 0.0 and 2.0 ms (n = 13). The c-l deviations above 2 ms were remote from other values and considered to be possibly inhibitory.(ABSTRACT TRUNCATED AT 400 WORDS)

Distribution of dendrites of mitral, displaced mitral, tufted, and granule cells in the rabbit olfactory bulb

To determine the dendritic fields, mitral, displaced mitral, middle tufted, and granule cells in the rabbit olfactory bulb were stained by intracellular injection of HRP. The secondary dendrites of mitral cells were distributed mostly in the inner half of the external plexiform layer (EPL). Those of displaced mitral cells extended mainly into the middle and superficial sublayers in the EPL. The secondary dendrites of middle tufted cells were distributed mostly in the superficial portion of the EPL. Mitral cells extended their secondary dendrites in virtually all directions within a plane tangential to the mitral cell layer (MCL) and thus had a disklike projection field with a radius of about 850 microns. Displaced mitral cells had similar dendritic projection fields in the tangential plane but with somewhat distorted shapes. The secondary dendrites of middle tufted cells had a tendency to extend in particular directions. From the projection pattern of the gemmules on the peripheral processes, granule cells were classified into three types. Type I granule cells had gemmules both in the superficial and in the deep sublayers of the EPL. The peripheral processes of Type II granule cells were confined to the deep half of the EPL. The gemmules of Type III granule cells ere distributed in the superficial half of the EPL. The differing dendritic ramification among mitral, displaced mitral, and middle tufted cells suggests the separation of the dendrodendritic synaptic interactions with granule cells in different sublayers in the EPL. It also suggests a functional separation of the sublayers of the EPL.

Different granule cell populations innervate superficial and deep regions of the external plexiform layer in rat olfactory bulb

Studies on the morphological organization of the main olfactory bulb have indicated that there are subpopulations of granule cells with different dendritic patterns in the external plexiform layer (EPL). Small, extracellular injections of horseradish peroxidase (HRP) were made iontophoretically into superficial and deep parts of the EPL and the granule cell layer (GCL) in adult rats. Superficial EPL injections principally labeled superficial granule cell somata, whereas deep EPL injections labeled both superficial and deep granule cell somata. Injections in the superficial GCL labeled granule cell dendritic processes extending across the entire EPL. However, deep GCL injections labeled few granule cell dendrites in the superficial EPL, but labeled many such processes in the deep EPL. These results were the same in material processed with the Hanker-Yates procedure, where the morphology of individual neurons could be studied, and in the more sensitive tetramethyl benzidine procedure. Serial reconstructions of individual granule cells were made from both HRP and Golgi-Kopsch material. The distal dendrites of deep granule cells reached only as far as the deep EPL, where they branched extensively and had many dendritic spines. The dendrites of superficial granule cells, however, reached the most superficial part of the EPL where they ramified most extensively. The superficial granule cells typically had a higher spine density in the superficial part of the EPL than in the deep part. On the basis of these results, we conclude that the superficial granule cells predominantly innervate the superficial EPL and that the deep granule cells exclusively influences on the bulbar output neurons, the mitral and tufted cells, through reciprocal dendrodendritic synapses. Since the secondary dendrites of the tufted cells ramify in the superficial EPL and the dentrites of most mitral cells ramify in deep EPL, the superficial and deep granule cells may preferentially modulate the responses of tufted and mitral cells, respectively.