Immunocytochemical localization of S-100 beta beta protein in olfactory and supporting cells of lamb olfactory epithelium

By immunocytochemistry, we have identified two novel cell types, olfactory and supporting cells of lamb olfactory epithelium, expressing S-100 beta beta protein. S-100 immune reaction product was observed on ciliary and plasma membranes, on axonemes and in the cytoplasm adjacent to plasma membranes and to basal bodies of olfactory vesicles. A brief treatment of olfactory mucosae with Triton X-100 before fixation is necessary for detection of S-100 beta beta protein within olfactory vesicles. In the absence of such a treatment, the immune reaction product is restricted to ciliary and plasma membranes. On the other hand, irrespective of pre-treatment of olfactory mucosae, S-100 beta immune reaction product in supporting cells is restricted to microvillar and plasma membranes. The anti-S-100 beta antiserum used in these studies does not bind to basal cells of the olfactory epithelium or to cells of the olfactory glands, whereas it binds to Schwann cells of the olfactory nerve. An anti-S-100 alpha antiserum does not bind to cellular elements of the olfactory mucosa, Schwann cells, or axons of the olfactory nerve. The present data provide, for the first time, evidence for the presence of S-100 beta beta protein in mammalian neurons (olfactory cells).     

Olfactory epithelium consisting of supporting cells and horizontal basal cells in the posterior nasal cavity of mice

The olfactory epithelium of mice generally consists of olfactory cells, progenitors of olfactory cells (globose basal cells), supporting cells, and horizontal basal cells. However, in the dorsal fossa (the roof) of the posterior nasal cavity of mice, we found seven epithelial patches consisting of only non-neuronal cell types, i.e., supporting cells and horizontal basal cells, among the normal olfactory epithelium. The supporting cells occupied three or four layers in the apical to middle regions; in the basal region, horizontal basal cells were localized in a single row adjacent to the basement membrane. Bowman's gland ducts were also present in the epithelium. Neuronal cells (olfactory cells and globose basal cells) were totally absent. The ultrastructure of the supporting cells, horizontal basal cells, and Bowman's glands was essentially similar to that in the normal olfactory epithelium. In the early postnatal period (P1-P7), cell types in the epithelium were the same as those in the normal olfactory epithelium. From P10 to P21, olfactory cells and globose basal cells had disappeared from the olfactory epithelium. At this period, the number of TUNEL-positive cells was significantly higher than that in the surrounding olfactory epithelium; ultrastructurally, many apoptotic figures were observed. This suggests that the epithelium consisting of supporting cells and horizontal basal cells is generated by the apoptotic death of olfactory cells and globose basal cells during postnatal development.     

Receptor cells of different types and quantitative relations between them in the organ of smell of larval and adult specimens of acipenserid fishes]

Three types of olfactory cells: rod-like and cone-like (flagellar olfactory cells) and filamentous (microvillar olfactory cells), which have been described previously in adult Acipenseridae were found in the olfactory organ of the ten-days larval sturgeons (Acipenser güldenst?dti), sevrugas (Acipenser stellatus) and sterlets (Acipenser ruthenus). The flagellar olfactory receptors appeared to predominate in both ten-days larvae and adults of the anadromous sturgeons and sevrugas, while the microvillar olfactory receptors predominate in freshwater sterlets in ten-days larvae as well in adults. The facts obtained confirm the idea that the rod-like, cone-like and filamentous olfactory cells are independent types of olfactory receptors. The different ratios of these cells in the olfactory organs of anadromous and fresh-water Acipenseridae may be a result of their ecological adaptations.     

Patterns of heterogeneous expression of pannexin 1 and pannexin 2 transcripts in the olfactory epithelium and olfactory bulb

Pannexins form membrane channels that release biological signals to communicate with neighboring cells. Here, we report expression patterns of pannexin 1 (Panx1) and pannexin 2 (Panx2) in the olfactory epithelium and olfactory bulb of adult mice. In situ hybridization revealed that mRNAs for Panx1 and Panx2 were both expressed in the olfactory epithelium and olfactory bulb. Expression of Panx1 and Panx2 was mainly found in cell bodies below the sustentacular cell layer in the olfactory epithelium, indicating that Panx1 and Panx2 are expressed in mature and immature olfactory neurons, and basal cells. Expression of Panx2 was observed in sustentacular cells in a few locations of the olfactory epithelium. In the olfactory bulb, Panx1 and Panx2 were expressed in spatial patterns. Many mitral cells, tufted cells, periglomerular cells and granule cells were Panx1 and Panx2 positive. Mitral cells located at the dorsal and lateral portions of the olfactory bulb showed weak Panx1 expression compared with those in the medial side. However, the opposite was true for the distribution of Panx2 positive mitral cells. There were more Panx2 mRNA positive mitral cells and granule cells compared to those expressing Panx1. Our findings on pannexin expression in the olfactory system of adult mice raise the novel possibility that pannexins play a role in information processing in the olfactory system. Demonstration of expression patterns of pannexins in the olfactory system provides an anatomical basis for future functional studies.     

基于小分子筛选的嗅上皮类器官培养体系的建立

嗅上皮接收和传导气味信号是嗅觉系统的重要组成部分。嗅上皮的损伤在通常情况下可自发恢复,但特定疾病或衰老造成的嗅上皮损伤会引起嗅觉功能减退和嗅觉障碍。嗅上皮主要由基底细胞、支持细胞以及嗅感觉神经元组成。为了在体外建立包含多种细胞类型的嗅上皮类器官,本研究采用3D细胞培养技术,通过筛选小分子药物,构建了包含多种细胞类型的嗅上皮类器官模型,包含水平基底样细胞、球形基底样细胞、支持样细胞和嗅感觉神经元样细胞多种细胞类型。类器官培养体系中多种生长因子和小分子化合物在细胞增殖速度、细胞组成以及不同细胞类型标志基因的表达水平等方面对类器官产生影响。Wnt信号通路激活剂CHIR-99021能够提高嗅上皮类器官的成克隆率和增殖速度且有利于提高嗅上皮类器官中嗅感觉神经元样细胞标志基因的表达水平;培养体系的任一因子均能提高类器官中cKit阳性的球形基底样细胞克隆比例;表皮生长因子(epidermal growth factor,EGF)和维生素C均有利于类器官中水平基底样细胞标志基因的表达。本研究建立的嗅上皮类器官系统模拟了嗅上皮干细胞分化产生多种嗅上皮细胞类型的过程,为研究嗅上皮组织损伤再生、嗅觉障碍病理...     

Olfactory ensheathing cells: their role in central nervous system repair

The olfactory system is an unusual tissue in that it can support neurogenesis throughout life; permitting the in-growth and synapse formation of olfactory receptor axons into the central nervous system (CNS) environment of the olfactory bulb. It is thought that this unusual property is in part due to the olfactory glial cells, termed olfactory ensheathing cells (OECs), but also due to neuronal stem cells. These glial cells originate from the olfactory placode and possess many properties in common with the glial cells from the peripheral nervous system (PNS), Schwann cells. Recent data has suggested that olfactory ensheathing cells are a distinct glial cell type and possess properties, which might make them more suitable for transplant-mediated repair of central nervous system injury models. This paper reviews the biological properties of these cells and illustrates their use in central nervous system repair.     

嗅鞘细胞的不同纯化方法及结果

培养的嗅鞘细胞的最终纯度受到多种因素的影响,如嗅鞘细胞的取材来源、分离方法等等;对培养的嗅鞘细胞进行纯化可获得高纯度的嗅鞘细胞。纯化嗅鞘细胞的方法有许多种,主要有单纯差速贴壁法、免疫吸附法、化学药物抑制法、无血清饥饿法等,现在的实验研究更趋向于以上2-3种方法联合应用对嗅鞘细胞进行纯化,这些联合纯化方案主要是在采用单纯差速贴壁方法的基础上再次运用其他一种或几种方法进行嗅鞘细胞的纯化。就获取的嗅鞘细胞的最终纯度而言,许多方法取得了可观的效果。但不同的纯化方法各有利弊,除了价格不同外,不同的纯化方法对嗅鞘细胞的生物活性造成不同程度的影响。因此在选择纯化方法时,应综合考虑各方面因素,根据研究目的和实际需要选择合理的方案进行纯化。本文通过查阅各数据库中与嗅鞘细胞的分离培养及纯化有关的文献和其他相关书籍,来探讨纯化嗅鞘细胞的不同方法以及这些纯化方法对嗅鞘细胞最终纯度的影响。     

The olfactory placodes of the zebrafish form by convergence of cellular fields at the edge of the neural plate

The primary olfactory sensory system is part of the PNS that develops from ectodermal placodes. Several cell types, including sensory neurons and support cells, differentiate within the olfactory placode to form the mature olfactory organ. The olfactory placodes are thought to arise from lateral regions of the anterior neural plate, which separate from the plate through differential cell movements. We determined the origins of the olfactory placodes in zebrafish by labeling cells along the anterior-lateral edge of the neural plate at times preceding the formation of the olfactory placodes and examining the later fates of the labeled cells. Surprisingly, we found that the olfactory placode arises from a field of cells, not from a discrete region of the anterior neural plate. This field extends posteriorly to the anterior limits of cranial neural crest and is bordered medially by telencephalic precursors. Cells giving rise to progeny in both the olfactory organ and telencephalon express the distal-less 3 gene. Furthermore, we found no localized pockets of cell division in the anterior-lateral neural plate cells preceding the appearance of the olfactory placode. We suggest that the olfactory placodes arise by anterior convergence of a field of lateral neural plate cells, rather than by localized separation and proliferation of a discrete group of cells.     

Transregulation of erbB expression in the mouse olfactory bulb.

Previously, we have shown that erbB-3 expression is restricted to the ensheathing cells of the olfactory nerve layer, while erbB-4 is found in the periglomerular and mitral/tufted cells of the olfactory bulb and in cells coming out from the rostral migratory stream of the subependymal layer. In the present work, we have treated adult mice with zinc sulfate intranasal irrigation and analyzed erbB-3 and erbB-4 expression in the deafferented olfactory bulb. Following treatment, olfactory axons undergo degeneration, as indicated by the loss of OMP expression in the deafferented olfactory bulb. The thickness of the olfactory nerve layer is reduced, but the specific intensity of erbB-3 labeling in the remaining olfactory nerve layer is increased with respect to control. Interestingly, following deafferentation, erbB-4 immunoreactivity decreases specifically in cell types that normally make synaptic contacts with primary olfactory neurons in the glomeruli, i.e. periglomerular and mitral/tufted cells. Partial lesion of the olfactory epithelium allows regenerative axon growth of olfactory neurons to the olfactory bulb. Following olfactory axon regeneration, erbB-3 and erbB-4 immunoreactivity in the olfactory bulb is similar to control. Thus, like tyrosine hydroxylase, the down regulation of erbB-4 expression in the periglomerular cells is reversible.     

Retrograde labeling and fine structure of olfactory receptor neurons in cat sharks

Ciliated and microvillar olfactory receptor cells have been reported in many fish species, including teleosts and elasmobranchs. Morphological studies have suggested that microvillar cells are the only olfactory receptor cells in the elasmobranchs; however, there is no direct evidence for this hypothesis. Here we used a cat shark (Scyliorhinus torazame) to determine the cell type of the olfactory receptor cells in elasmobranchs. Retrograde labeling with a fluorescent dye, Dil, labeled only cells in the second layer from the surface of the olfactory epithelium, suggesting that ciliated cells located in the surface layer are not olfactory receptor cells. In addition, electron microscopic observation revealed that the labeled cells in the second layer have a thin dendritic knob extending from the cell body to the free surface of the epithelium. A part of the dendritic knob facing the mucous layer did not have ciliary structures. These results provide evidence that the aciliate cells are the only olfactory receptor cells in the cat shark olfactory organ.     

成年大鼠嗅鞘细胞与嗅觉神经成纤维细胞的原代培养及鉴定

目的 建立一种原代提取嗅鞘细胞与嗅觉神经成纤维细胞混合培养的方法.方法 自2.5月龄SD大鼠嗅球最外两层分离嗅鞘细胞和嗅觉神经成纤维细胞进行混合培养,并不进行纯化,分别于7 d、10 d、14 d行免疫细胞化学鉴定,并计算各个时间点嗅鞘细胞的纯度.结果 体外培养的嗅鞘细胞主要呈两极或多极状,而嗅觉神经成纤维细胞则成扁平的像成纤维细胞的形态,免疫细胞化学结果显示嗅鞘细胞呈p75 NGFR阳性,嗅觉神经成纤维细胞呈fibronectin阳性,两种细胞都呈vimentin阳性,在7 d、10 d、14 d各个时间点嗅鞘细胞分别占混合培养的34.1%、25.6%、8.6%.结论 从成年大鼠嗅球最外两层分离的培养中主要包含嗅鞘细胞和嗅觉神经成纤维细胞,嗅鞘细胞在混合培养中所占的比例随培养时间的延长而逐渐降低.     

The glucose transporter GLUT1 and the tight junction protein occludin in nasal olfactory mucosa.

The nervous cells in the brain and the peripheral nerves are isolated from the external environment by the blood-brain, blood-cerebrospinal fluid and blood-nerve barriers. The glucose transporter GLUT1 mediates the specific transfer of glucose across these barriers. The olfactory system is unique in that its sensory cells, olfactory receptor neurons, are embedded in the nasal olfactory epithelium and send their axons directly to the olfactory bulb of the brain. Only the apical parts of the olfactory receptor neurons are exposed to the lumen, and these serve as sensors for smell. Immunohistochemical examination showed that the tight junction protein occludin was present in the junctions of the olfactory epithelium. Endothelial cells in the blood vessels in the lamina propria of the olfactory mucosa were also positive for occludin. These observations suggest that the olfactory system is guarded from both the external environment and the blood. GLUT1 was abundant in these occludin-positive endothelial cells, suggesting that GLUT1 may serve in nourishing the cells of the olfactory system. Taken together, GLUT1 and occludin may serve as part of the machinery for the specific transfer of glucose in the olfactory system while preventing the non-specific entry of substances.     

Expression of cell adhesion molecules in the olfactory system of the adult mouse: presence of the embryonic form of N-CAM

The expression of the neural cell adhesion molecules N-CAM and L1 was investigated in the olfactory system of the mouse using immunocytochemical and immunochemical techniques. In the olfactory epithelium, globose basal cells and olfactory neurons were stained by the polyclonal N-CAM antibody reacting with all three components of N-CAM (N-CAM total) in their adult and embryonic states. Dark basal cells and supporting cells were not found positive for N-CAM total. The embryonic form of N-CAM (E-N-CAM) was only observed on the majority of globose basal cells, the precursor cells of olfactory neurons, and some neuronal elements, probably immature neurons, since they were localized adjacent to the basal cell layer. Differentiated neurons in the olfactory epithelium did not express E-N-CAM. In contrast to N-CAM total, the 180-kDa component of N-CAM (N-CAM180) and E-N-CAM, L1 was not detectable on cell bodies in the olfactory epithelium. L1 and N-CAM180 were strongly expressed on axons leaving the olfactory epithelium. Olfactory axons were also labeled by antibodies to N-CAM180 and L1 in the lamina propria and the nerve fiber and glomerular layers of the olfactory bulb, but only some axons showed a positive immunoreaction for E-N-CAM. Ensheathing cells in the olfactory nerve were observed to bear some labeling for N-CAM total, L1, and N-CAM180, but not E-N-CAM. In the olfactory bulb, L1 was not present on glial cells. In contrast, N-CAM180 was detectable on some glia and N-CAM total on virtually all glia. Glia in the nerve fiber layer were labeled by E-N-CAM antibody only at the external glial limiting membrane. In the glomerular layer, E-N-CAM expression was particularly pronounced at contacts between olfactory axons and target cells. The presence of E-N-CAM in the adult olfactory epithelium and bulb was confirmed by Western blot analysis. The continued presence of E-N-CAM in adulthood on neuronal precursor cells, a subpopulation of olfactory axons, glial cells at the glia limitans, and contacts between olfactory axons and their target cells indicates the retention of embryonic features in the mammalian olfactory system, which may underlie its remarkable regenerative capacity.     

Histochemical studies on the distribution of some enzymes of the glycolytic pathways in the olfactory bulb of the squirrel monkey (Saimiri sciureus)

Summary Detailed histochemical studies on the distribution of glycolytic enzymes have been made in the olfactory bulb of the Squirrel Monkey. The olfactory glomeruli, mitral cells, tufted cells, glial cells and nerve fibers are well equipped with the enzymes of the glycolytic pathways. Granule cells do not have the ability to synthesize or breakdown glycogen, but they have the Embden-Meyerhof-Parnas pathway and the Warburg-Dickens pathway. The synapses of the olfactory glomeruli may have the ability to break-down glycogen for an energy source. Small glial cells found in the olfactory glomeruli may be a special type of oligodendrocyte. Glial cells found abundantly in and around the olfactory glomeruli may be energy donators to the synapses of the olfactory glomeruli. It is suggested that oligodendrocytes and astrocytes of the olfactory bulb may have different branching enzymes.Visiting scientist from Anatomy Department, Tokyo Medical and Dental University, Tokyo, Japan. T. R. Shanthaveerappa in previous publications.     

Distinct distribution of four Ca2+-dependent subtypes of protein kinase C in rat olfactory bulb; definite expression of betaII-subtype in the accessory olfactory bulb

The localization of four subtypes of Ca2+-dependent protein kinase C (PKC) in the main and accessory olfactory bulb was examined by immunocytochemistry by using specific antibodies against each PKC subtype. In the main olfactory bulb, alpha-PKC was densely localized in a large number of granule cells and in a few tufted cells, and faint immunoreactivity was seen in some periglomerular cells. betaI-PKC was intensely found in periglomerular cells and tufted cells. gamma-PKC immunoreactivity was present in the external plexiform layer, the internal plexiform layer, and the granular layer, but the immunoreactivity was found only in the neuropils. Little, if any, betaII-PKC was seen in the main olfactory bulb. On the other hand, the intense immunoreactivity for betaII-PKC was seen in periglomerular cells of the accessory olfactory bulb. The betaI-PKC and gamma-PKC were also present in periglomerular cells of the accessory olfactory bulb, while alpha-PKC was localized only in granule cells. Double staining study in the accessory olfactory bulb showed that betaII-PKC was present in the GABAergic periglomerular cells, while betaI-PKC localized to the non-GABAergic periglomerular cells; gamma-PKC was expressed in both GABAergic and non-GABAergic cells. These findings suggest that four calcium-dependent subtypes of PKC play different roles in the olfactory bulb and definite expression of betaII-PKC strongly suggested the involvement of this subtype in a specific function in the accessory olfactory bulb.     

Ultrastructural aspects of olfactory transduction and perireceptor events

Ultrastructural/immunocytochemical studies with well defined antibodies suggest that distal segments of olfactory cilia are the main sites of early events in olfactory signal transduction. Such studies also begin to provide specifics of the cytoskeletal make-up of olfactory epithelial cells, but knowledge about relationships between cytoskeletal and transduction components is still incomplete. Probes to less well defined chemical entities, but that distinctly label olfactory cilia, supporting cell microvilli and microvilli of microvillous cells, may serve as markers for further studies on olfactory signaling. Ultrastructural/immunocytochemical studies also suggest that supporting cells help to balance the mucous environment of olfactory cilia.     

Neuronal degeneration and regeneration in the olfactory epithelium of pigeon following transection of the first cranial nerve.

The pigeon olfactory nerve has been sectioned to explore the course of retrograde degeneration of the sensory neurons' perikarya, which are located in the olfactory neuroepithelium. Both light- and electron-microscopic observations have shown that from 3 to 8 days after axotomy the sensory neurons undergo retrograde, irreversible degeneration. Following disappearance of the mature neurons, the basal cells of the neuroepithelium actively divide and differentiate into mature olfactory sensory neurons. Consequently, the basal cells represent true stem cells of the olfactory sensory neurons. The olfactory mucosa regains a structural organization close to normal in a period of 30-50 days after axotomy. These observations indicate that, when the primary olfactory neurons degenerate as a consequence of the experimental section of their axons, restitutio ad integrum of the sensory olfactory connections can be reestablished by new elements which differentiate from basal cells of the olfactory neuroepithelium.20     

Immunocytochemistry of the olfactory marker protein.

The olfactory marker protein has been localized, by means of immunohistochemical techniques in the primary olfactory neurons of mice. The olfactory marker protein is not present in the staminal cells of the olfactory neuroepithelium, and the protein may be regarded as indicative of the functional stage of the neurons. Our data indicate that the olfactory marker protein is present in the synaptic terminals of the olfactory neurons at the level of the olfactory bulb glomeruli. The postsynaptic profiles of both mitral and periglomerular cells are negative.     

Structure of the olfactory bulb in tadpoles of Xenopus laevis

The structure of the olfactory bulb in tadpoles of Xenopus laevis (stages 54-56) was studied using axon tracing (with biocytin or low-weight dextran) and immunocytochemical techniques. Filling the olfactory nerve with biocytin made the nerve layer and the glomeruli visible. Dye injections into the glomerular layer labeled the lateral olfactory tract. Vice versa, dye injections into the lateral olfactory tract made mitral cells and their glomerular branching patterns visible. Anti-GABA antiserum stained periglomerular and granule cells, while the olfactory nerve and mitral cells were labeled by antiglutamate antiserum. We describe the layering, the numbers of cells and glomeruli, and their localization in both the main and the accessory olfactory bulb.     

Reciprocal interactions between olfactory receptor axons and olfactory nerve glia cultured from the developing moth Manduca sexta

In olfactory systems, neuron-glia interactions have been implicated in the growth and guidance of olfactory receptor axons. In the moth Manduca sexta, developing olfactory receptor axons encounter several types of glia as they grow into the brain. Antennal nerve glia are born in the periphery and enwrap bundles of olfactory receptor axons in the antennal nerve. Although their peripheral origin and relationship with axon bundles suggest that they share features with mammalian olfactory ensheathing cells, the developmental roles of antennal nerve glia remain elusive. When cocultured with antennal nerve glial cells, olfactory receptor growth cones readily advance along glial processes without displaying prolonged changes in morphology. In turn, olfactory receptor axons induce antennal nerve glial cells to form multicellular arrays through proliferation and process extension. In contrast to antennal nerve glia, centrally derived glial cells from the axon sorting zone and antennal lobe never form arrays in vitro, and growth-cone glial-cell encounters with these cells halt axon elongation and cause permanent elaborations in growth cone morphology. We propose that antennal nerve glia play roles similar to olfactory ensheathing cells in supporting axon elongation, yet differ in their capacity to influence axon guidance, sorting, and targeting, roles that could be played by central olfactory glia in Manduca.