In the mammalian cochlea, there are two independent gap junction systems, the epithelial cell gap junction system and the connective tissue cell gap junction system. Thus far, four different connexin molecules, including connexin 26, 30, 31, and 43, have been reported in the cochlea. The two networks of gap junctions form the route by which K+ ions that pass through the sensory cells during mechanosensory transduction can be recycled back to the endolymphatic space, from which they reenter the sensory cells. Activation of hair cells by acoustic stimuli induces influx of K+ ions from the endolymph to sensory hair cells. These K+ ions are released basolaterally to the extracellular space of the organ of Corti, from which they enter the cochlear supporting cells. Once inside the supporting cells they move via the epithelial cell gap junction system laterally to the lower part of the spiral ligament. The K+ ions are released into the extracellular space of the spiral ligament by root cells and taken up by type II fibrocytes. This uptake incorporates K+ into the connective tissue gap junction system. Within this system, the K+ ions pass through the tight junctional barrier of the stria vascularis and are released within the intrastrial extracellular space. The marginal cells of the stria vascularis then take up K+ and return it to the endolymphatic space, where it can be used again in sensory transduction. It is highly probable that mutations of connexin genes that result in human nonsyndromic deafness cause dysfunction of cochlear gap junctions and thereby interrupt K+ ion recirculation pathways. In addition to connexin mutations, other conditions may disrupt gap junctions within the ear. For example, mice with a functionally significant mutation of Brain-4, which is expressed in the connective tissue cells within the cochlea, show marked depression of the endolymphatic potential and profound sensorineural hearing loss. It seems likely that disruption of connective tissue cells by this mutation disrupts K+ ion entry into the stria vascularis and thereby results in loss of endolymphatic potential. The association of sensorineural hearing loss with these genetic disorders provides strong evidence for the necessity of gap junction systems for the normal functioning of the cochlea.
The human oviduct is lined with a simple columnar epithelium composed of ciliated cells and secretory cells. Primary cilia or solitary cilia usually extend from the apical surface of the secretory cells. The axoneme of the primary cilia is composed of nine peripheral microtubule doublets (9 + 0 pattern) that lack dynein arms and nexin links. Displacement of peripheral doublets to the central region, which is suggested to be attributable to the lack of nexin links, is one of the distinctive features of oviductal primary cilia. The basal body that extends the primary cilium connects to its paired centriole by the striated connector. The basal body is associated with the accessory structures, such as alar sheets, basal feet, and striated rootlets. Several basal feet project laterally from the basal body. The cap of the basal foot serves as the microtubule organizing center. Several striated rootlets radiate from the basal body toward the nucleus. The basal body, the paired centriole, and the basal body-associated structures are considered to play important roles in the stabilization and fixing of the cilium in the proper position on the apical cell surface.
Striated rootlets in ciliated cells are conical banded structures composed of longitudinally aligned filaments. The formation of striated rootlets during ciliognesis in the human oviduct epithelium was studied by electron microscopy. Primitive rootlets appeared at the proximal side of basal bodies before or at the same time as ciliary budding. After the formation of several striations, the tip of the rootlets extended deeply toward the interior of the cell and became differentiated into two distinct parts, viz., the proximal conical part connected to the basal body and the distal fibrillar part. The periodicity of the striations in the fibrillar part was 68. 5+/-2.95 nm, about 5 nm longer than that of the conical part (63. 9+/-2.25 nm). The dark band in the striation was thicker in the fibrillar part than in the conical part. Since the fibrillar part was not observed in the mature cilium, this part was considered as being either degraded or changed into the conical part during ciliogenesis.
The human oviduct epithelium primarily consists of ciliated cells and secretory cells. Solitary cilia usually extend from the apical surface of the secretory cells. We investigated the localization of gamma-tubulin in the ciliary basal apparatus of both cell types by fluorescence immunohistochemistry and immunoelectron microscopy. In addition to basal bodies, gamma-tubulin was identified in the lateral basal foot, especially the basal foot cap. This observation is consistent with previous observations that microtubules radiate from the basal foot and the basal foot serves as the microtubule organizing centre.
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