Methods for cellular and subcellular visualization of intermediate filament proteins in the human inner ear

Apoptosis in the human inner ear. Detection by in situ end-labeling of fragmented DNA and correlation with other markers

The aim of this study was to obtain baseline data on the recently described special form of single cell death, apoptosis, in normal human inner ears. For this purpose, in situ end-labeling of the fragmented DNA was applied, in conjunction with apoptosis-related markers, to detect cellular elements showing programmed cell death in decalcified and paraffin-embedded tissues. Over 20 specimens were analyzed which were obtained from autopsy cases with no history of acoustic lesions confirmed by histopathology. Based on staining results, we saw no apoptotic signs in the majority of normal adult inner ears. An apoptotic cell captured in the Reissner's membrane of the cochlea from an old patient may, however, indicate an age-related subtle cell loss with the process of apoptosis. Nevertheless, the fact that more apoptosis was not found in our cases suggests that this phenomenon does not contribute significantly to the tissue homeostasis in the adult inner ear under normal conditions. These data are in accordance with our immunohistochemical findings on the p53 nucleoprotein, and proliferating cell nuclear antigen expression since there was no staining in any of the cellular elements, including the mesenchymal cells. This reflects a stationary and stable condition of cells of the vestibular and the cochlear structures, probably to maintain their integrity and the fine sensory functions. As opposed to the above findings, during inner ear development, the epithelial cells lining the cochlear lumen, the ossifying cartilage of the temporal bone, and the mesenchymal cells show different degrees of proliferation in combination with single cell death as signs of maturation of the vestibular and the cochlear apparatus. In addition, apoptosis has been demonstrated in cells of the cochlear stria vascularis from an adult patient treated with high doses of cisplatin, vinblastine and bleomycin prior to death. Furthermore, a wide range of apoptosis could be induced experimentally in a normal ear by an external perfusion of actinomycin D (ActD), which is known to produce programmed cell death in many cell types of different origins. The potential role of cytostatic agents in the apoptotic process of the inner ear needs, however, to be confirmed in large-scale specimens from patients treated with genotoxins. The fact, however, that apoptotic cells are also seen in association with ActD indicates that the fine sensory structure of the cochlea may also be a target for certain chemotherapeutic agents when administered in high doses.

Cytoskeletal proteins in human hair cells

Human cochlear and vestibular hair cells (HCs) were analysed for the three major cytoskeletal types of structures: microfilaments, microtubules, and intermediate filaments and several of their associated proteins. Specific immunomorphological features were identified: the apical surface, the infracuticular rod of F-actin, the cytoplasm and the HC bases and their interactions with adjacent supporting cells. There is morphological evidence for at least three functionally interacting units: the OHC as a cytoskeletal string interacting with the Deiter's cell, being a part of the rigid pancellular protein shell of the organ of Corti; compartmentalization of HCs (surrounded by rigid intermediate filament proteins in the supporting cells); and a calcium-guided short-loop feed-back control of type I HCs. The cytoskeletal composition of all four types of human HCs and their adjacent structures is similar to, although not identical with, corresponding compositions in other mammalian species.

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.

Protein patterns in human vestibular ganglion cells and hair cells, with functional interpretations

Cytoskeletal organization was analysed in the vestibular ganglion cells and in the sensory epithelia of all five vestibular organs of the adult human temporal bone. A pancellular rigidity of the upper surfaces of the vestibular organs, evidenced by large quantities of intermediate filaments and actin, seems of importance for the mechanoelectrical transduction by opposing the motion of the cupulae and statoconial layers. Immunostaining for the calcium-binding protein synaptophysin in the sensory hair bundles and in the area close to the cuticular plates--the first of its kind to be demonstrated in human vestibular organs--indicates the presence of calcium-dependent ionic channels. The hypothesis is presented that the calyx might be involved in a short-loop feed back control of type I hair cells, i.e. of the mechanoelectrical transduction itself. Subpopulations of vestibular ganglion cells were identified by the staining pattern of cytoskeletal proteins, but not by ordinary ultrastructural analysis.

Effects of monomeric acrylic embedding media on the antigenicity of two epitopes of the MIC2-encoded Ewing's sarcoma cell membrane antigen

Comparative electron microscopic studies of pre- and postembedding immunolabeling experiments have shown that the antigenicity of some epitopes is lost during acrylic resin embedding of the respective tissues. In the present investigation we have tested the sensitivities of two embedding-labile epitopes (HBA-71 and HBA-45) of the Ewing's sarcoma-associated MIC2-encoded E2 antigen to the effects of the different treatment steps, which are necessary for the preparation of ultrathin sections. The extent of antigenic retention was quantitated using flow cytometry and enzyme-linked immunosorbent assays (ELISA) of tumor cell lines, thymocytes and cell membrane extracts. Fixation, dehydration and high temperature treatment of MIC2-positive cells showed only minor effects on the reactivity with the HBA-71 and HBA-45 antibodies. However, exposure of the cells to the monomeric acrylic resins LR White (LRW), LR Gold (LRG) and Lowicryl K4M at 4 degrees C for 2-18 h resulted in a significant reduction of the HBA-71 and HBA-45 reactivities. In contrast, the antigenicity of both epitopes was maintained during treatment with the apolar Lowicryl HM20 embedding medium under these non-polymerizing conditions. The resins have no direct effect on the HBA-71/HBA-45 antigen, since it could be extracted in intact form from membranes of native, but not of fixed, tumour cells using LRW for membrane solubilization. These data indicate that the HBA-71/HBA-45 antigen remains in the cell membrane and is indirectly influenced by the extraction/modification of adjacent membrane constituents. The adverse effects of the polymerization process, in the case of embedding at low temperature in Lowicryl HM20, destroyed MIC2-antigenicity.(ABSTRACT TRUNCATED AT 250 WORDS)

Regional variations in the expression of cytokeratin proteins in the adult human cochlea

In the adult human cochlea, a cytokeratin (Ck) network exists along the entire surface of the organ of Corti, enclosing it like a shell. Only the surfaces of the outer and inner hair cells are not integrated in this network. In temporal bone specimens, Ck filaments in Hensen's cells were found to be arranged parallel with and closely apposed to the plasma membrane. In the stria vascularis, Cks were identified only in the marginal cells. Cells in Reissner's membrane and spiral prominence showed varying degrees of immunoreactivity to different monoclonal antibodies directed against Cks. A distinct positivity for Cks was found in most spiral ganglion cells, indicating their presence in all cells. The principal pattern of immunoreactivity was the same in the organ of Corti of the entire cochlea. However, a quantitative gradient in the expression of Cks was observed, with more Cks at the apex than at the base. This was correlated to a difference in the number of Hensen's cells between the two regions. The distinct shell configuration of the Ck network in Corti's organ gives it a tonotopically related difference in rigidity which must be of considerable importance for the perception of sound in the cochlea. The absence of Cks in inner and outer sulcus cells gives them cytoskeletal characteristics of mesenchymal cells with a possible regenerative potential.