Archives of Histology and Cytology 66 巻, 5 号

Formation and organization of the mammalian sperm head

The formation and organization of a mammalian sperm head occurs through diverse cellular and molecular processes during spermiogenesis. Such cellular events include sequential changes in the nucleus and the acrosome-which is derived from the Golgi apparatus-in concert with prominent bundles of microtubules, the manchette. However, these complex processes are readily impaired by a variety of intrinsic and extrinsic factors, eventually causing various types of male infertility-such as teratozoospermia-which include the deformation of the acrosome and nucleus. In order to comprehend such idiopathic male infertility syndromes, it is important to clarify the mechanism involved in sperm head formation and organization. In addition to the manchette, two key structures in these events are the acroplaxome and the perinuclear theca. The acroplaxome forms the acrosome plate with periodic intermediate filament bundles of the marginal ring at the leading edge of the acrosome, and its nature has recently been characterized. The perinuclear theca, which is located in the perinuclear region in the sperm head, contains not only a cytoskeletal element to maintain the shape of the sperm head but also functional molecules leading to oocyte activation during fertilization.
This review discusses recent developments regarding the formation and organization of the mammalian sperm head in relation to its relevant functions.

Localization of lymphocyte apoptosis in murine lymphoid tissues after stimulation of natural killer T cells with alpha-galactosylceramide

Alpha-galactosylceramide (α-GalCer) has been reported to induce activation-induced cell death (AICD) in natural killer T (NKT) cells. We undertook this study to demonstrate the distribution of AICD of NKT cells in the lymphoid tissues and differences in frequency between the central and peripheral lymphoid tissues, histologically and quantitatively analyzing the apoptotic figure in the murine spleen, lymph node, and thymus after α-GalCer treatment. Lymphocyte apoptosis was identified as a cluster of nuclei with chromatin condensation in hematoxylin-eosin-stained sections, and was confirmed by TUNEL staining, double staining for TUNEL and CD4, and electron microscopy. In the spleen, it appeared at 12 h after α-GalCer administration, increased in number, reaching a peak at 24 h, and then falling to a normal level at 72 h. It was preferentially found in the white pulp, especially in the periarterial lymphoid sheath, but was sparse in the red pulp. Alpha-GalCer-induced lymphocyte apoptosis was seen in tumor-necrosis factor (TNF)-deficient mice as well, but was not in lpr/lpr (Fas-deficient) or gld/gld (Fas ligand-deficient) mice. As for the tissue distribution, lymphocyte apoptosis was frequently seen in the paracortex of the lymph node, whereas it was rare in the thymus. These data indicate that α-GalCer-induced AICD of NKT cells takes place in the T-cell area of peripheral lymphoid tissues (i.e., the spleen and lymph node) through the Fas/Fas ligand, but not the TNF pathway.

The ultrastructure of periductal connective tissue and distinctive populations of collagen fibrils associated with ductal epithelia of exocrine glands

The ultrastructure of the connective tissue around the intraglandular ducts was observed in rat exocrine glands. Connective tissue with a dense population of collagen fibrils was found either around the ducts and blood vessels (perivasculoductal connective tissue; PVDCT) as in the lacrimal and salivary glands and liver, or solely surrounding the ducts (periductal connective tissue; PDCT) as in the exocrine pancreas, whereas the interlobular and intralobular interstitium of the glands—except for the liver—contained substantially fluid-filled spaces without collagen fibrils. The PVDCT and PDCT of these glands contained two populations of collagen fibrils—fibroblast-associated and epithelium-associated—although the development and density of these fibrils varied considerably in individual glands. Both populations of collagen fibrils were most developed in the lacrimal glands, in which the basal aspects of the ductal epithelium and the basement membrane showed considerable undulation associated with a distinctive peribasement membrane zone with amorphous matter and a small population of the fibrils. In the parotid and submandibular glands, both populations were distinct, though poorly developed. In the exocrine pancreas and hepatic Glisson’s sheath, the two populations of collagen fibrils were moderately developed, and the basal aspects of the ductal epithelium were characterized by prominent invaginations in which the multilaminar basement membranes and the epithelium-associated collagen fibrils were frequently engulfed. These observations provide evidence that the two populations of collagen fibrils around the ducts are found universally in exocrine glands, and support the hypothesis of the collagen fibril-synthesizing and -secreting ability of ductal epithelial cells.

Extracellular matrix-regulated p53 expression and nuclear localization in cultured Detroit 562 cells derived from pharyngeal carcinoma

Tumor suppressor p53 functions as a transcriptional factor that regulates the cell cycle and apoptosis. A mutated p53 gene can result in decreased sequence-specific DNA binding and transcriptional activity of the p53 protein. In this study, we examined the regulatory role of the extracellular matrix components in p53 expression and nuclear localization in a Detroit 562 cell line derived from a pharyngeal carcinoma. When cultured on a polystyrene surface, type I collagen gel, or Matrigel containing basement membrane components, Detroit 562 cells showed a distinct response to extracellular matrix components morphologically. As shown by Western blotting, Detroit 562 cells cultured on Matrigel displayed an increased expression of p53 protein as well as an elevated nuclear p53 level, as compared with the cells cultured on the polystyrene surface or type I collagen gel. When cultured on Matrigel, nuclear p53-positive cells were exclusively localized to the outer surface layer of the cell clusters, whereas most of the inner cells showed no p53 expression. In Detroit 562 cell clusters on Matrigel, proliferative activities, as evaluated by proliferation cell nuclear antigen staining and bromo-deoxyuridine incorporation assay, were evenly distributed; virtually no apoptotic cells, as evaluated by the fluorescence TUNEL assay, were detected in the cell clusters, suggesting that the peculiar localization of nuclear p53-positive cells was not directly related to cell proliferation or apoptosis. These results indicate that p53 expression and its localization in Detroit 562 cells were modulated by extracellular matrix signals, particularly by the basement membrane components in Matrigel.

Selective expression of L-serine synthetic enzyme 3PGDH in Schwann cells, perineuronal glia, and endoneurial fibroblasts along rat sciatic nerves and its upregulation after crush injury

Non-essential amino acid L-serine functions as a highly potent, glia-derived neurotrophic factor, because it is a precursor for syntheses of proteins, other amino acids, membrane lipids, and nucleotides, and also because its biosynthetic enzyme 3-phosphoglycerate dehydrogenase (3PGDH) is preferentially expressed in particular glial cells within the brain. Here we pursued 3PGDH expression in peripheral nerves and its change after crush injury. In the pathway of rat sciatic nerves, 3PGDH was selectively expressed in non-neuronal elements: Schwann sheaths and endoneurial fibroblasts in sciatic nerves, satellite cells in dorsal root ganglia, and astrocytes and oligodendrocytes in the spinal ventral horn. In contrast, 3PGDH was immunonegative in axons, somata of spinal motoneurons and ganglion cells, and endoneurial macrophages. One week after crush injury, 3PGDH was upregulated in the distal segment of injured nerves, where 3PGDH was intensified in activated Schwann cells and fibroblasts. 3PGDH was still negative in activated macrophages, which were instead associated or surrounded by activated Schwann cells with intensified 3PGDH. These results suggest that in the peripheral nervous system, these non-neuronal cells synthesize and may supply L-serine to satisfy metabolic demands for maintenance and regeneration of peripheral nerves and for proliferation and activation of macrophages upon nerve injury.

The Expression of cytokeratin in hepatic stellate cells of the cod

In the current study, we examined the cytoskeletal architecture of cod hepatic stellate cells. We found that the cod hepatic stellate cells contain abundant cytoplasmic filaments. Deep-etch electron microscopy showed that the major component of the cytoplasmic filaments was intermediate filaments, although microtubules and microfilaments were also found in the cytoplasmic filament bundles. Immunoelectron microscopy revealed the presence of β-tubulin, α-smooth muscle actin, smooth muscle type myosin, desmin and cytokeratin but not vimentin or glial fibrillar acidic protein. These results demonstrate that the cytoplasmic filaments of cod hepatic stellate cells are composed of desmin and cytokeratin intermediate filaments, acto-myosin complexes and microtubules, suggesting that the cod hepatic stellate cells have both contractile and structural functions. The expression of cytokeratin in cod hepatic stellate cells indicates that they serve for mechanical support in the extremely soft liver tissues of cods with their abundant lipids.

Localization and expression of chondromodulin-I in the rat cornea

The localization and expression in the rat cornea of chondromodulin-I (ChM-I), an inhibitory angiogenesis factor, were examined by immunohistochemistry, Western blot analysis, ribonuclease protection assay, and real-time PCR assay. We found immunoreactivity for ChM-I in the epithelial layer but not the stromal layer or endothelial layer in the cornea, in addition to the positive ChM-I immunoreactivity in other sites in the eye such as the sclera, retina, and ciliary body. The ChM-I immunoreactivity was most intense at the outside of the basal cells and in their cytoplasm while the intensity of the immunoreactivity decreased gradually from the wing cells to the superficial cells in the corneal epithelial layer. No reactivity however, was detected in the Bowman’s membrane or conjunctival epithelial cells which had continuity with the corneal epithelial cells. The expression of ChM-I mRNA was demonstrated in the cornea at one-third less intensity than that in the sclera with choroids and retinal pigment epithelium by ribonuclease protection assay and real-time PCR. ChM-I in the corneal epithelial layer may prevent neovascularization and maintain avascularity in the cornea.

Embryonic development of the myenteric nerve plexus in the rat small intestine as revealed by light and scanning electron microscopy

This study was performed to clarify developmental changes in the structure of the myenteric nerve plexus in the rat small intestine. The small intestines of fetal and neonatal rats were examined by light microscopic immunohistochemistry for protein gene product 9.5 (PGP-9.5) and α-smooth muscle actin (α-SMA). Direct observation of the three-dimensional structure of the neuronal and muscular elements was accomplished by scanning electron microscopy of tissues after KOH treatment.
At the embryonic day 14 (E14), PGP-9.5 immunopositive (neuronal) cells first appeared in the mesenchymal tissue outside an α-SMA positive (muscle) cell layer. These cells increased in number to form a thin and continuous sheet, which was sandwiched between the inner and outer muscular layers at E17. This neuronal layer consisted of immature ganglion cells associated with supportive (enteroglial) cells, and was gradually segregated into groups by incomplete separation through slit-like interruptions at E18. With the widening of these slits at E19, the neuronal sheet was observed as a ladder composed of transversely elongated ganglia and their connecting nerve strands, resulting in the typical structure of the myenteric nerve plexus. Fibroblastic cells of a peculiar shape appeared on the outer surface of the myenteric plexus at E19. These cells (presumably interstitial cells) interconnected their long branching projections to form a cellular network on the myenteric plexus until birth.

Human blood group antigen H is not the specific marker for type I cells in the taste buds

We examined the localization of human blood antigen H (AbH) and its correlation with other cell type markers in the taste buds of circumvallate papillae of the adult rat. Immunoreactivity for AbH was localized in the membrane of two cell populations in the taste buds: in spindle-shaped cells extending from base to the apical portion of the taste buds as well as in round-shaped cells at the basal portion of the taste buds. Quantitative analysis revealed that approximately 47.8%, 24.4%, and 14.6% of cells within the taste buds displayed AbH-, α-gustducin- or protein gene product 9.5 (PGP 9.5)-immunoreactivity, respectively. Approximately 16.3% and 6.6% of AbH-immunoreactive taste bud cells displayed α-gustducin- or PGP 9.5-immunoreactivity, respectively. Although previous studies proposed that AbH immunoreactivity was specific for type I cells (dark cells or supporting cells), the present results indicate that AbH immunoreactivity is also present in some type II cells (α-gustducin immunoreactive cells) and type III cells (PGP 9.5-immunoreactive cells).