Trigeminal ganglion neurons comprise three main cell body-size types. This cell size heterogeneity provides an excellent neuronal model to study the cell size-dependent organization and dynamics of the nucleoli, Cajal (coiled) bodies (CBs), and nuclear speckles of pre-mRNA splicing factors, nuclear structures that play a key role in the normal neuronal physiology. We have analyzed the number of nucleoli and CBs and the structural and molecular organization of CBs and nuclear speckles in the three neuronal types by using immunofluorescence with antibodies that recognize nucleoli (fibrillarin), CBs (coilin), and nuclear speckles (snRNPs), confocal microscopy, and electron microscopy. Whereas the mean number of nucleoli per neuron decreases as a function of cell size, the number of CBs per cell significantly increases in large neurons in comparison with the small ones. In addition, large neurons have a higher proportion of CBs associated with the nucleolus. In all neuronal types, CBs concentrate coilin, fibrillarin, snRNPs, and the survival motor neuron protein (SMN). Immunostaining for snRNPs shows small speckle domains and extensive areas of diffuse nucleoplasmic signal in large neurons, in contrast with the large nuclear speckles found in small neurons. Furthermore, flow cytometric analysis shows that all neurons are in the range of diploid cells. These findings indicate that the fusion behavior of nucleoli, the formation of CBs and their relationships with the nucleolus, as well as the compartmentalization of the pre-mRNA splicing machinery, is related to cell body size in the trigeminal ganglion neurons. Because transcriptional activity is a basic determinant mechanism of cell size in diploid cells, we suggest that our findings reflect a distinct transcription-dependent organization of the nucleolus and splicing machinery in the three cell types of trigeminal ganglion neurons.
The three-dimensional (3D) microanatomy of the cornea is the major determinant of its optical and mechanical properties. Scanning electron microscopy (SEM) is the most commonly used method to obtain information on the overall 3D microanatomy of organs. However, SEM has not been successful in revealing the 3D microanatomy of the cornea, because the interior of the cornea is too compact to be explored by the electron beam. In this study, the 3D organisation of the cells and extracellular materials of human and rabbit corneas was examined after exposure by HCl and NaOH digestion, and by microdissection by the adhesive tape method. In the cornea of both species, all epithelial cells exhibited microplicae regardless of their location. This raises doubts about the tear film-holding role assigned to the microplicae of the superficial cells. Human and rabbit corneas differed in the collagen fibre patterns of the epithelial basement membranes. The 3D organisation of the stromal lamellae was similar in both species. In humans and rabbits, the keratocytes showed similar 3D features. However, the surface of human keratocytes located near Descemet's membrane exhibited small fenestrations that were not present in the rabbit keratocytes. The pattern of keratocyte innervation by the stromal neural plexus and 3D keratocyte microanatomy confirms that keratocytes form a large intercommunicating network within the corneal stroma. Two morphologically discrete subpopulations of keratocytes located at different stromal levels were identified in both human and rabbit corneas, suggesting that keratocytes are not functionally homogeneous. In addition, the density of the stromal neural plexus appeared to be greater in rabbits than in humans. Clear differences between human and rabbit corneas were observed in the collagen arrangement in Descemet's membrane, which may reflect their different biomechanical requirements.
Intranuclear inclusions composed of tubular filaments constitute a pathological hallmark of oculopharyngeal muscular dystrophy (OPMD). Autosomal dominant OPMD is caused by (GCG) repeat expansions in the gene that encodes for poly(A) binding protein nuclear 1 (PABPN1). The mutation results in the expansion of a polyalanine stretch in the N-terminus of the protein. It has been proposed that mutated PABPN1 induces protein aggregation, which in turn causes the formation of the filamentous nuclear inclusions. Here we report the presence of intranuclear inclusions composed of tubular filaments in oxytocin-producing neurons from normal rat hypothalamus. Like OPMD inclusions, the filamentous structures in neurosecretory neurons accumulate PABPN1, poly(A) RNA, ubiquitin and proteasomes. These inclusions do not contain members of Hsp40 and HDJ-2/DNAJ families of chaperones. The proportion of oxytocin-producing neurons that contain inclusions decreases during parturition and lactation (when synthesis and release of oxytocin is maximal) and increases at 1 day post-weaning (when occurs a drastic reduction in the production of the hormone). Thus, PABPN1 filaments in normal neurons are dynamic structures, the appearance of which correlate with changes in cellular activity. These data provide the first physiological evidence that polyalanine expansions are not essential to induce polymerization of PABPN1 into filamentous nuclear inclusions.
The Dipnoi (lungfishes) have developed true lungs, having the ability to take oxygen from both the gills and the lungs. During the tropical dry season, many lungfish estivate on land, breathing only air. The estivation period is accompanied by profound functional modifications, including the suppression of urine. Thus, the lungfish kidney must be designed to cope with these dramatic cyclic changes in renal function. We study here the microanatomy and the structure of the kidney of the African lungfish Protopterus dolloi, maintained under controlled freshwater conditions. Chemical microdissection, light microscopy, and scanning and transmission electron microscopy have been used. The nephrons of P. dolloi are composed of a renal corpuscle (RC) and of a renal tubule that appears divided into five morphologically distinct segments: neck segment (NS), proximal tubule (PT), intermediate segment (IS), distal tubule (DT), and collecting tubule (CT). Paired CTs abut into a collecting duct, the latter emptying into an archinephric duct. The RCs lie in the mid-zone of the kidney, between the PTs and the convoluted DTs. The spatial distribution of these elements allows recognition of a kidney zonation. The RCs group into clusters (3-4 RCs per cluster) that are supplied by a single arteriole surrounded by pericytes. Each cluster appears to represent a functional unit with a common hemodynamic regulatory mechanism. The major processes of the podocytes form flattened networks that appear to constitute an integrated system due to the presence of gap junctions. The existence of mesangial cells with large cell processes, and of mesangial cells with a dendritic appearance, suggests a complex functional role (contractile and phagocytic) for the mesangium. The NS and the IS are the narrowest nephron segments, formed only by multiciliated cells. The PT and the DT can be subdivided, based on the tubular morphology and on cell composition, into portions I and II: PTI is formed only by brush border (BB) cells, while PTII contains BB and multiciliated cells. The DTI is formed by segment-specific cells, while the DTII contains segment-specific and a small number of flask cells. The CT contains principal and flask cells in a 5:1 ratio. The flask cells adopt two different configurations (with a narrow canaliculus or with a large cavity). The main goal of this study was to disclose specific kidney features that could be related to function, phylogeny, and habitat. In addition, the present results constitute the basis for a study of the morphologic changes that should occur in the kidney of P. dolloi during estivation. Anat Rec Part A, 288A: 609 -625, 2006.
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