Expression of intermediate filaments and desmoplakin in vertebrate olfactory mucosa

Neuronal Homeostasis in Mammalian Olfactory Epithelium: A Review

The neuronal lineage of the olfactory epithelium (OE) is a cell lineage that includes the neuronal stem cell and its progeny (ultimately the mature olfactory receptor neuron [ORN]). Recent studies, including further characterization of the neuronal lineage of the OE, and of factors that influence proliferation, survival, and death of cells of this lineage, have contributed significantly to understanding of neuronal homeostasis, i.e., normal maintenance of neuronal number, in mammalian OE. Our recent studies indicate that in adult mice, all cell types of the neuronal lineage of the OE—neuronal precursors, immature ORNs and mature ORNs—undergo constitutive death, i.e., a normal, basal level of cell death, that is characteristic of programmed cell death or apoptosis. To some extent, constitutive cell death in this lineage may reflect random environmental insults; however, this may also be the result of an ongoing developmental program that acts to control both numbers and phenotypic organization of olfactory neurons. Although a variety of extrinsic and intrinsic factors are likely to contribute to cell death in the neuronal lineage of the OE, most have not been thoroughly studied. Detailed analysis of one of these factors, effects of target deprivation, suggests that survival of individual cell types of the neuronal lineage of the OE may be differentially regulated with mature ORNs, but not immature ORNs or neuronal precursors, dependent upon the olfactory bulb for their survival. Factors normally provided to cells of the ORN lineage, as in other neuronal systems, are likely to promote survival by inhibiting an endogenous genetic program of cell death. Whether candidate polypeptide growth factors, e.g., the neurotrophins, or other pharmacological inhibitors of apoptosis will eventually play a role in the treatment of specific anosmias remains to be determined.

Timing of neuronal intermediate filament proteins expression in the mouse vomeronasal organ during pre- and postnatal development. An immunohistochemical study

Several types of intermediate filament proteins are expressed in developing and mature neurons; they cooperate with other cytoskeletal components to sustain neuronal function from early neurogenesis onward. In this work the timing of expression of nestin, peripherin, internexin, and the neuronal intermediate filament triplet [polypeptide subunits of low (NF-L), medium (NF-M), and high (NF-H) molecular weight] was investigated in the developing fetal and postnatal mouse vomeronasal organ (VNO) by means of immunohistochemistry. The results show that the sequence of expression of intermediate filament proteins is internexin, nestin, and NF-M in the developing vomeronasal sensory epithelium; internexin, peripherin, and NF-M in the developing vomeronasal nerve; and nestin, internexin and peripherin, NF-L, and NF-M in the nerve supply to accessory structures of the VNO. At sexual maturity (2 months) NF-M is only expressed in vomeronasal neurons and NF-M, NF-L and peripherin are expressed in extrinsic nerves supplying VNO structures. The differential distribution of intermediate filament proteins in the vomeronasal sensory epithelium and nerve is discussed in terms of the cell types present therein. It is concluded that several intermediate filament proteins are sequentially expressed during intrauterine development of the VNO neural structures in a different pattern according to the different components of the VNO.

Cytoskeletal polypeptides: cell-type specific markers useful in investigative otorhinolaryngology

In the last decade, it has been established that eukaryotic cells possess a cytoskeleton, i.e. an integrated cytoplasmic network of microfilaments (MFs), microtubules (MTs) and intermediate filaments (IFs). Moreover, certain cell membrane specializations as well as the inner lamina of the nuclear membrane also participate in the cytoskeletal structure. Although this definition of the cytoskeleton is up to date it is obvious that the future course of cell biology will be reflected in a revised definition. While the bulk of structural polypeptides involved were characterized at regular intervals, surprisingly, the function of the cytoskeleton remained largely speculative and is still less precisely defined. The most widely postulated function concerns mechanical support and integration of diverse cellular activities and thus refers to cellular architecture. Briefly, the mechanical function is thought to involve cell movement, adhesive interaction with the extracellular matrix and neighbouring cells, as well as the stabilization of cell shape. The integrative function refers to intracellular movement, i.e. transport and positioning to the appropriate locations of organelles, intracellular particles, RNA and proteins. It has been established from numerous investigations that (certain) cytoskeletal polypeptides provide significant information about the cellular origin and differentiation state. This consideration constitutes the most prominent reflection underlying this review. Furthermore, this appreciation encourages additional efforts to explore these markers in normal and pathological conditions. The first purpose of this review is briefly to summarize our present comprehension of the molecular components of the cytoskeleton, restricted to the filamentous trinity for practical reasons. The second and main aim is to survey the field with respect to otorhinolaryngology-related issues. To the author's knowledge, this has not been dealt with in the past. In bridging this gap in the literature, I hope to provoke additional interest in one of the fastest moving areas of cell biology. A comprehensive review covering the whole cytoskeleton has been covered by Preston et al. (The Cytoskeleton and Cell Motility. Blackie, Glasgow and London, 1990, pp. 7-69, 188-191). Additional information on the participating substructures is provided in the text, inclusive of last year's reviews.

Purified cultures of keratin-positive olfactory epithelial cells: identification of a subset as neuronal supporting (sustentacular) cells

The mammalian olfactory neuroepithelium, lining part of the nasal cavity, retains into adulthood progenitor cells for the olfactory receptor neurons and other cell types in the epithelium. The details of cellular lineage relationships are not completely understood. In particular, the exact nature of the interactions between several progenitor cell types and their relationship to neurons is not known. Studies of this system have been hampered by the lack of cell culture models and insufficient cell-type-specific markers. Antibodies to the cytokeratins are fairly specific markers for one potential progenitor cell type, the dark basal cells of the olfactory epithelium. Keratin immunostaining was used to develop cell culture systems which contained large numbers of putative dark basal cells, using the soft nasal mucosal tissues of both newborn and adult rats. Media and substrate conditions were optimized. The conditions which supported growth of keratin-positive nasal cells for greater than one month, and allowed partial purification, suggested similarities between olfactory and skin keratinocytes. Immunostaining with a monoclonal antibody specific for sustentacular cells (SUS-1) showed a subset of these cells present in culture, with some cells double-labelled with anti-keratin. This staining confirms the olfactory origin of at least a subset of the cells, and supports the proposal that the majority of cells were the dark olfactory basal cells. This culture system gives novel insights into olfactory epithelial cell physiology, and allows culture of these cells for further studies examining regulation of differentiation.

Differential spatial and temporal expression of two type III intermediate filament proteins in olfactory receptor neurons

Olfactory receptor neurons (ORNs) do not express the typical neuronal intermediate filament proteins (IFPs), the neurofilament triplet proteins. Immunocytochemical evidence shows that ORNs coexpress vimentin and peripherin but distribute them differently. Specifically, ORNs contain vimentin in dendrites, cell bodies, and axons, but not in terminals in glomeruli; peripherin is present in axons, but excluded from dendrites, cell bodies, and terminal glomeruli. In adult rats, ORN axon fascicles are variably stained with antisera for peripherin; in juvenile rats, staining of fascicles is uniform. Staining with antibody to vimentin is uniform in both adult and juvenile ORN axon fascicles. The unusual pattern of IFP expression and intracellular sorting may have implications for the unique plastic and regenerative capacities of these neurons.

Rat olfactory neurons express a 200 kDa neurofilament

Neurofilament expression in peripheral olfactory neurons of adult rats was investigated by immunoblotting and immunohistochemistry using monoclonal antibodies specific for each of the 3 neurofilament proteins. Immunoblotting analysis of olfactory epithelium extracts demonstrated the presence of only the 200 kDa (NFH) polypeptide; the 68 kDa (NFL) and 160 kDa (NFM) neurofilaments were not detected. Similarly, no immunoreactivity was observed in tissue sections using the NFL and NFM antibodies. In contrast, when sections were probed with the antibody to NFH, immunoreactivity was localized primarily in the dendritic knobs and near the cell bodies of the receptor cells.

Keratins in the developing olfactory epithelia

At embryonic day 14, the supporting cells of the olfactory epithelium already contained tonofilaments which terminated in the desmosomes, and were stained by antikeratin antibodies of RGE53 and MA902, indicating the presence of 45 and 52.5 kDa keratins. The basal cells were identified at postnatal day 1 by the appearance of a few filaments, and stained by PKK2 antikeratin antibody which reacts with 40, 46, 48, and 54 kDa keratins, and by CKB1 antikeratin antibody which reacts with 50 kDa keratin. At postnatal day 14, the basal cells possessed densely aggregated bundles of filaments and reacted with KL1 and MA902 antikeratin antibodies, indicating the appearance of 56 and 52.5 kDa keratins. The basal cells showed a columnar or pyramidal shape changing into a flat shape during postnatal development. The olfactory cells remained unstained by antikeratin antibodies throughout their development.

Molecular physiology of olfaction

Olfactory reception is mediated by olfactory receptor cells located in the olfactory epithelium. These cells are bipolar neurons that extend a dendrite toward the nasal lumen and an axon toward the olfactory bulb in the brain. The dendrite possesses a group of apical cilia embedded in mucus. Odorant recognition and signal transduction are initiated at the membranes of these chemosensory cilia and culminate in excitation of the olfactory receptor cell. Differential activation by odorants of distinct groups of olfactory receptor cells generates patterns of neuronal activity that encode odor quality and concentration. The identities of primary odorant recognition sites at the ciliary membrane remain to be established. However, a significant body of information has become available with respect to olfactory transduction mechanisms. It is now becoming clear that olfactory transduction involves the interplay of several second messenger systems to control the responses of these exquisitely sensitive chemosensory neurons.