Electrophysiology of interneurons in the glomerular layer of the rat olfactory bulb

In the mammalian olfactory bulb, glomeruli are surrounded by a heterogeneous population of interneurons called juxtaglomerular neurons. As they receive direct input from olfactory receptor neurons and connect with mitral cells, they are involved in the initial stages of olfactory information processing, but little is known about their detailed physiological properties. Using whole cell patch-clamp techniques, we recorded from juxtaglomerular neurons in rat olfactory bulb slices. Based on their response to depolarizing pulses, juxtaglomerular neurons could be divided into two physiological classes: bursting and standard firing. When depolarized, the standard firing neurons exhibited a range of responses: accommodating, nonaccommodating, irregular firing, and delayed to firing patterns of action potentials. Although the firing pattern was not rigorously predictive of a particular neuronal morphology, most short axon cells fired accommodating trains of action potentials, while most delayed to firing cells were external tufted cells. In contrast to the standard firing neurons, bursting neurons produced a calcium-channel-dependent low-threshold spike when depolarized either by current injection or by spontaneous or evoked postsynaptic potentials. Bursting neurons also could oscillate spontaneously. Most bursting cells were either periglomerular cells or external tufted cells. Based on their mode of firing and placement in the bulb circuit, these bursting cells are well situated to drive synchronous oscillations in the olfactory bulb.     

Long-distance fiber outgrowth from the heterotopically transplanted olfactory bulb in the rat

An embryonic olfactory bulb was heterotopically inserted and allowed to mature in young adult rat brains. The projection of the transplanted olfactory bulb to the host brain was examined by injections of peroxidase-labeled wheatgerm agglutinin into the host olfactory bulb (and anterior olfactory nucleus). Neurite elongation to the host olfactory area occurred most frequently from the transplant which had been inserted into the anterior horn of the lateral ventricle and fused medially with the lateral septum in host brains with no detectable damage of host olfactory connections. Transplants in the septum, olfactory tubercle, nucleus of the horizontal limb of the diagonal band, or anterior piriform cortex also showed the projection to the host olfactory area. These results indicate that the transplanted olfactory bulb projection neurons have potent abilities to detect the target and project to it even if there is a considerable distance (2-5 mm).     

Aspartate-like immunoreactivity in mitral cells of rat olfactory bulb

Antisera against aspartate (Asp) were prepared by immunizing rabbits with Asp conjugated to bovine serum albumin by glutaraldehyde, after which the antisera were purified using an Asp-immobilized epoxy-activated affinity column. The purified Asp antiserum showed no cross-reactivity, except for a 3% cross-reactivity against D-Asp. Asp-like immunoreactivity in mitral cells of the rat olfactory bulb was demonstrated, using this purified Asp antiserum.     

Dendrodendritic recurrent excitation in mitral cells of the rat olfactory bulb.

Most neuronal interactions within the olfactory bulb network are mediated by dendrodendritic synapses. Dendritic transmitter release potentially could affect the parent dendrite as well as local neuronal elements that have receptors for the released transmitter. Here we report that under conditions that facilitate N-methyl-D-aspartate (NMDA) receptor activity (reduced GABAA inhibition and extracellular Mg2+), a single action potential evoked by brief intracellular current pulses in mitral cells is followed by a prolonged depolarization, which is blocked by an NMDA receptor antagonist. This depolarization also is evoked by a presumed calcium spike in the presence of tetrodotoxin. A similar NMDA-receptor-dependent prolonged depolarization is elicited by stimulation of the lateral olfactory tract at current intensities subthreshold for antidromic activation of the recorded neuron. These observations suggest that glutamate released from the dendrites of mitral cells excites the same and neighboring mitral cell dendrites. Further evidence suggests that both the apical and lateral dendrites of mitral cells participate in this recurrent excitation. These dendrodendritic interactions may play a role in the prolonged, NMDA-receptor-dependent depolarization of mitral/tufted cells evoked by olfactory nerve stimulation.     

人胚胎嗅球嗅鞘细胞的制备

目的 探讨人胚胎嗅鞘细胞(OECs)培养与纯化的优化方法.方法 取3～5个月流产胚胎,无菌条件下取出嗅球,解剖镜下仔细剥离嗅球表面的软膜组织和血管,消化后用条件培养基制成密度为106个细胞/ml细胞悬液,利用差速贴壁法结合阿糖胞苷抑制法进行无血清纯化液细胞纯化培养,对不同培养时期进行观察和行P75NGFR(低亲和力神经...     

Response properties of mitral cells in the olfactory bulb of the neonatal rat

Activity was recorded from mitral cells in newborn to six-day-old rat pups during odorous stimulation. Twenty-eight neurons were studied in pups with unopened nasal cavities which sampled stimuli during intermittent periods of inhalation. Forty-six neurons were studied in pups with opened nasal cavities which were stimulated by delivering odorants directly to the olfactory epithelia. We show that mitral cells are selectively excited by different odorants on the day pups are born; prior to the maturation of bulb interneurons, the responses of neonatal mitral cells are time-locked to the inhalation cycle; neonatal mitral cells preserve the temporal patterns of activity exhibited by receptor neurons during stimulation with different concentrations of odorants; and the response patterns of mitral cells differ qualitatively between newborn and adult rats.We conclude that receptor-to-mitral cell synapses are functional in newborn rat pups and that the activity of this afferent pathway is modulated by the pups' respiratory behavior. We argue that without interneurons, mitral cells repeat the temporal code exhibited by receptor neurons and do not produce the types of response patterns characteristic of neurons in the adult rat olfactory bulb.     

Microglial activation in the developing rat olfactory bulb

The development of the olfactory bulb, the primary central relay of the olfactory system, is characterized by a striking susceptibility to alterations in the amount of afferent input. For example, blocking airflow through one half of the nasal cavity during early life results in a number of dramatic changes in the bulb, including increased cell death. Previous studies reveal high levels of microglia in the olfactory bulb. Microglia function as phagocytes, aid in synaptogenesis, and produce important trophic and cytotoxic factors. In response to a number of tissue perturbations, microglia undergo an activation process that includes, among other changes, the up-regulation of complement receptor 3. Interestingly, a previous study reported that naris closure had no effect on microglia in the bulb; however, the research did not distinguish the functional activation state of microglia. We further examined the role of microglia in the normally developing and olfactory-deprived rat bulb using immunohistochemical detection of complement receptor 3 as a measure of microglial activation. Expression of the receptor in the bulb is relatively high during postnatal development, in particular when compared to levels in cortical regions caudal to the olfactory bulb. In addition, naris closure performed on the day after birth (but not after the first postnatal month) increases levels of the receptor in an age and laminar-dependent fashion.The presence of an inducible pool of activated microglia in the olfactory bulb may be important for normal development and contribute to the plethora of changes seen after early olfactory deprivation.     

Evidence for an absence of K+ spread in the glomerular layer of the rat olfactory bulb

Using K+-sensitive microelectrodes inserted into the olfactory bulb, the effects of distant K+ ejection on the extracellular K+ activity (aK), were monitored in the glomerular and plexiform layers. A ouabain-sensitive mechanism, which appeared to be markedly more efficient in the glomerular layer, prevents spread of distal ejected K+. The results are discussed on the basis of Na+,K+-pump activation in both glomerular neuronal networks and the glial capsule enclosing each glomerulus.     

Spatial coding of enantiomers in the rat olfactory bulb

Because of their unique properties, enantiomers (pairs of mirror-symmetric, nonsuperimposable molecules that differ only in optical activity and their interaction with other chiral molecules) have been instrumental in demonstrating that olfactory perception relies on molecular shape. To investigate how molecular structure is encoded by the olfactory system, we combined behavioral discrimination tasks with optical imaging of intrinsic signals. We found that rats can behaviorally discriminate members of a wide range of enantiomer pairs, and imaging revealed enantiomer-selective glomeruli in the olfactory bulb, indicating that the spatial pattern of glomerular activity provides sufficient information to discriminate molecular shape.     

Frequency-dependent modulation of inhibition in the rat olfactory bulb

We analyzed postmortem tissues of sporadic amyotrophic lateral sclerosis (SALS) for mRNA levels of two inflammatory proteins, complement C1qB and clusterin (apoJ). By Northern blot hybridization, SALS was associated with increased mRNA for C1qB and clusterin in the motor cortex (Brodmann area A4), but not in superior temporal cortex (A17), relative to neurologically normal controls. By in situ hybridization, SALS spinal cords showed increased C1qB and clusterin mRNA in areas undergoing neurodegeneration. This evidence implicates inflammatory mechanisms during neurodegenerative processes in SALS.     

Synaptology of cultured olfactory bulb cells

Cultured embryonic mouse olfactory bulb cells formed asymmetric, symmetric, axodendritic, and dendrodendritic synapses. These neurons contained electron lucent, dense core, and coated vesicles. Dense core and coated vesicles had an average diameter of 71 and 80 nm, respectively. Two statistically different populations of electron lucent vesicles were found, based on synaptic symmetry: electron lucent vesicles from asymmetric synapses had an average diameter of 46 nm with an estimated volume of 49,000 nm³, whereas those from symmetric synapses had an average diameter of 44 nm and an estimated volume of 42,000 nm³. Because these values are similar to those found for intact olfactory bulb, the synapses of these cultured cells have some of the same morphological characteristics as those in the intact olfactory bulb.     

Odor response properties of neighboring mitral/tufted cells in the rat olfactory bulb

Olfactory perception initiates in the nasal epithelium wherefrom olfactory receptor neurons--expressing the same receptor protein--project and converge in two different glomeruli within each olfactory bulb. Recent evidence suggests that glomeruli are isolated functional units, arranged in a chemotopic manner in the olfactory bulb. Exposure to odorants leads to the activation of specific populations of glomeruli. In rodents, about 25-50 mitral/tufted cells project their primary dendrites to a single glomerulus receiving similar sensory input. Yet, little is known about the properties of neighboring mitral/tufted cells connected to one or a few neighboring glomeruli. We used tetrodes to simultaneously record multiple single-unit activity in the mitral cell layer of anesthetized, freely breathing rats while exposed to mixtures of chemically related compounds. First, we characterized the odorant-induced modifications in firing rate of neighboring mitral/tufted cells and found that they do not share odorant response profiles. Individual units showed a long silent (11.01 ms) period with no oscillatory activity. Cross-correlation analysis between neighboring mitral/tufted cells revealed negligible synchronous activity among them. Finally, we show that respiratory-related temporal patterns are dissimilar among neighboring mitral/tufted cells and also that odorant stimulation results in an individual modification that is not necessarily shared by neighboring mitral/tufted cells. These results show that neighboring mitral/tufted cells frequently exhibit dissimilar response properties, which are not consistent with a precise chemotopic map at the mitral/tufted cell layer in the olfactory bulb.     

人胚嗅球嗅鞘细胞原代培养的实验研究

目的拟建立人胚胎嗅球嗅鞘细胞的培养方法并探讨这些细胞在活性、纯度方面是否具备临床应用水平。方法用含有促进细胞生长的谷氨酰胺、转铁蛋白、生物素、硒酸纳的无血清纯化液纯化嗅鞘细胞,胰蛋白酶消化收集细胞,制成单细胞悬液。采用台盼蓝染色法进行活性测定,P75NGFR和S-100双标免疫荧光染色鉴定,以Hoechst复染鉴定OECs的纯度。结果可见比较典型的嗅鞘细胞:双极或梭形、多突起形和扁圆形,主要以梭形和多突起形细胞为主。细胞活性大于95%,纯度大于90%。结论实验建立的人胚胎嗅球嗅鞘细胞原代培养的方法可行,细胞活性大于95%,纯度和均一性已达到临床应用水平。     

Calcium-binding protein parvalbumin-immunoreactive neurons in the rat olfactory bulb

The laminar distribution and morphological features of parvalbumin-immunoreactive [PV(+l)] neurons, one of the subpopulations of GABAergic neurons, were studied in the rat olfactory bulb at a light microscopic level. In the main olfactory bulb of adult rats, PV(+) neurons were mainly located in the external plexiform layer (EPL), and a few were scattered in the glomerular layer (GL), mitral cell layer (ML), and granule cell layer (GRL); whereas PV(+) neurons were rarely seen in the accessory olfactory bulb. The inner and outer sublayers of the EPL (ISL and OSL) appeared to be somewhat different in the distribution of PV(+) somata and features of PV(+) processes. PV(+) somata were located throughout the OSL, and PV(+) processes intermingled with one another, making a dense meshwork in the OSL; whereas, in the ISL, PV(+) somata were mainly located near the inner border of the EPL, and PV(+) processes made a sparser meshwork than that in the OSL. PV(+) neurons in the EPL were apparently heterogeneous in their structural features and appeared to be classifiable into several groups. Among them there appeared five distinctive types of PV(+) neurons. The most prominent group of PV(+) neurons in the OSL were superficial short-axon cells, located in the superficial portion of this sublayer and giving rise to relatively thick processes, in horizontal or oblique directions, which usually bore spines and varicosities. Another prominent group of PV(+) neurons extended several short, branched dendrites with spines and varicosities, which appeared to intermingle with one another, making a relatively small, spherical or ovoid dendritic field around the cell bodies; most of them resembled Van Gehuchten cells reported in previous Golgi studies. A third distinctive and most numerous group of PV(+) neurons were of the multipolar type; their somata and processes were located throughout the EPL. Their relatively smooth processes with frequent varicosities and a few spines were extended horizontally or diagonally throughout the EPL. A fourth group, which could be a subtype of the multipolar type, were located in or just above th ML and extended several thin, smooth dendrites in the EPL, some of which appeared to reach the border between the GL and EPL. Occasionally, axonlike processes arose from their cell bodies and extended into the ML. This fourth type of PV(+) neuron was named inner short-axon cells. A fifth group of neuron was located in the ML; processes of these neurons were extended horizontally, so they were named inner horizontal cells. PV(+) processes from the fourth and the fifth group of cells appeared to make contacts on mitral cell somata. In the GL some presumably periglomerular cells were also PV(+). In the GRL, PV(+) neurons were small in number, but they were also heterogeneous in their structural features; Some were identified as Golgi cells. This study shows a tremendous heterogeneity in morphological features of a chemically defined subpopulation of GABAergic interneurons in the olfactory bulb.     

Odor representation and discrimination in mitral/tufted cells of the rat olfactory bulb

Extracellular single-unit responses to odorants with various properties were recorded from mitral/tufted cells over large areas of the olfactory bulb of anesthetized rats. Each cell was exposed to one stimulus set consisting of five different odorants each at five concentrations. The resulting concentration-response profiles were compared. All mitral/tufted cells examined responded to two or more odorants, and the largest proportion of the cells were sensitive to all five odorants. Cells unresponsive to all five odorants regardless of concentration were not observed. Mitral/tufted cells sensitive to all three of the odorants that are known to evoke maximal electro-olfactograms in different regions of the olfactory epithelium were distributed widely throughout the olfactory bulb. There were no significant differences in latencies of odor responses either across recording sites or across odorants. A comparison of the concentration-response profiles suggested that all of the mitral/tufted cells were equally capable of responding to any odorant with their own distinctive pattern, but that the cells tended to show an identical pattern rather than variable pattern of response to different odorants. Five mitral/tufted cells isolated within 800 m of one electrode track showed different concentration-response profiles. Of 18 simultaneously recorded spike pairs with different amplitudes and discharge patterns recorded incidentally through one electrode at different sites, 10 had different and 8 had identical response patterns to odorants. These results suggest that: (1) mitral/tufted cells are sensitive to a broad spectrum of odorants, but respond with their own patterns to odorants; (2) odor discrimination is not uniform in neighboring cells, and a discrimination unit is comprised of a single cell.     

Migration of bipolar subependymal cells, precursors of the granule cells of the rat olfactory bulb, with reference to the arrangement of the radial glial fibers

In order to examine the relationship between radial glial fibers and the migrating bipolar subependymal cells which are considered to be post-mitotic precursors of granule cells in the rat olfactory bulb, the arrangement of radial glial fibers along the anterior lateral and olfactory ventricles was analysed by Golgi techniques, immunohistochemical demonstration of glial fibrillary acidic protein, and electron microscopy. In rats during their first 3 weeks of life, the bipolar subependymal cells migrate along the anterior lateral and olfactory ventricles into the center of the olfactory bulb, whereas the radial glial fibers radiating from the ventricular surface are arranged rather perpendicularly to the direction of migration of bipolar cells. Hence radial glial fibers in this region are not considered to act as guides for the rostralwards migration of subependymal cells.     

Synaptic connectivity of serotonergic axons in the olfactory glomeruli of the rat olfactory bulb

Although the major mode of transmission for serotonin in the brain is volume transmission, previous anatomical studies have demonstrated that serotonergic axons do form synaptic contacts. The olfactory glomeruli of the olfactory bulb of mammals receive a strong serotonergic innervation from the dorsal and medial raphe nuclei. In the present report, we investigate the synaptic connectivity of these serotonergic axons in the glomerular neuropil of the rat olfactory bulb. Our study shows that serotonergic axons form asymmetrical synaptic contacts on dendrites within the glomerular neuropil. Analyzing the neurochemical nature of the synaptic targets, we have found that 55% of the synapses were on GABA-immunopositive profiles and 45% on GABA-immunonegative profiles. These data indicate that barely half of the contacts were found in GABA-immunonegative profiles and half of the synapses in GABA-positive dendrites belonging to type 1 periglomerular cells. Synaptic contacts from serotonergic axons on dendrites of principal cells cannot be excluded, since some of the GABA-immunonegative postsynaptic profiles contacted by serotonergic axons had the typical ultrastructural features of bulbar principal cell dendrites. Altogether, our results suggest a complex action of the serotonergic system in the modulation of the bulbar circuitry.