Restricted nutrition-induced low birth weight, low number of nephrons and glomerular mesangium injury in Japanese quail.

Insufficient nutrition during the perinatal period causes structural alterations in humans and experimental animals, leading to increased vulnerability to diseases in later life. Japanese quail, Coturnix japonica, in which partial (8-10%) egg white was withdrawn (EwW) from eggs before incubation had lower birth weights than controls (CTs). EwW birds also had reduced hatching rates, smaller glomeruli and lower embryo weight. In EwW embryos, the surface condensate area containing mesenchymal cells was larger, suggesting that delayed but active nephrogenesis takes place. In mature EwW quail, the number of glomeruli in the cortical region (mm2) was significantly lower (CT 34.7±1.4, EwW 21.0±1.2); capillary loops showed focal ballooning, and mesangial areas were distinctly expanded. Immunoreactive cell junction proteins, N-cadherin and podocin, and slit diaphragms were clearly seen. With aging, the mesangial area and glomerular size continued to increase and were significantly larger in EwW quail, suggesting compensatory hypertrophy. Furthermore, apoptosis measured by terminal deoxynucleotidyl transferase-mediated dUTP-biotin nick-end labeling analysis was higher in EwWs than in CTs on embryonic day 15 and postnatal day 4 (D4). Similarly, plasma glucocorticoid (corticosterone) was higher (P<0.01) on D4 in EwW quail. These results suggest that although nephrogenic activity is high in low-nutrition quail during the perinatal period, delayed development and increased apoptosis may result in a lower number of mature nephrons. Damaged or incompletely mature mesangium may trigger glomerular injury, leading in later life to nephrosclerosis. The present study shows that birds serve as a model for 'fetal programming,' which appears to have evolved phylogenetically early.

Anti-perforin antibody treatment ameliorates experimental crescentic glomerulonephritis in WKY rats.

The depletion of CD8+ cells has been shown to prevent the initiation and progression of antiglomerular basement membrane (GBM) crescentic glomerulonephritis (GN) in Wistar-Kyoto (WKY) rats. In this study, we asked whether CD8+ cells produce their effects by perforin/granzyme-mediated or by Fas ligand (FasL)-mediated pathways. The glomerular mRNA expression of perforin and granzyme B corresponded with the number of CD8+ cells, whereas that of granzyme A, Fas, and FasL did not. The enhanced mRNA level of perforin and granzyme B was not evident in CD8+-depleted rats. The number of apoptotic cells in the glomeruli was significantly increased at day 3. Perforin mRNA was found in cells infiltrating the glomerulus by in situ hybridization and by using dual-staining immunohistochemistry perforin protein was found in glomerular CD8+ cells. We found that perforin was readily visualized at the inner surface of the glomerular capillaries by immunoelectron microscopy. Based on these results, we treated animals with a perforin antibody in vivo and found that it significantly reduced the amount of proteinuria, frequency of crescentic glomeruli, and the number of glomerular monocytes and macrophages, although the number of glomerular CD8+ cells was not changed. Our results suggest that CD8+ cells play a role in glomerular injury as effector cells in part through a perforin/granzyme-mediated pathway in the anti-GBM WKY rat model of crescentic GN.

An improved method for primary culture of rat podocytes.

A gentle method to isolate glomeruli simply by cutting renal cortices without forced sieving was devised in our previous study of primary podocyte culture. Yields of glomeruli isolated by this method, however, were too small to perform subculture or biological assays. In the present study, we tried an isolation method with magnetic beads and collagenase to increase the yields. Rat kidneys were perfused with magnetic particles. Renal cortices were digested with collagenase and filtered. Utilizing magnetic particles trapped within glomeruli, glomeruli were collected by attractive power of a magnet and cultured. The number of glomeruli isolated from one adult rat was more than 20,000 and the purity was more than 97%. About half of them were attached to culture dishes and exhibited cellular outgrowths, which were identified as podocytes by their distinct staining for podocyte markers. After 3 days of primary culture, the cellular outgrowths were subcultured. Approximately 60 podocytes were obtained per attached glomerulus. Their significant expression of podocytes markers was demonstrated by immunostaining and quantitative reverse transcriptase-polymerase chain reaction. The isolation method with magnetic beads and collagenase provides a number of glomeruli suitable for primary podocyte culture.

Cloning of a new aquaporin (AQP10) abundantly expressed in duodenum and jejunum.

A new aquaporin (AQP10) was identified in human small intestine. This gene encoded a 264-amino-acid protein with high sequence identity with AQP3 (53%), 9 (52%), and 7 (43%). These AQPs constitute one subfamily of AQP family that is differentiated from the other subfamily of AQP (AQP0, 1, 2, 4, 5, 6, and 8) by sequence homology. Ribonuclease protection assay and Northern blotting demonstrated almost exclusive expression of AQP10 mRNA in the duodenum and jejunum. In situ hybridization localized it in absorptive jejunal epithelial cells. Xenopus oocytes expressing AQP10 exhibited an increased osmotic water permeability in a mercury-sensitive manner. Although AQP10 belongs to the AQP subfamily, which has been characterized by permeability to water and neutral solutes such as urea and glycerol, it was not permeable to urea nor glycerol. The specific expression of AQP10 suggests its contribution to the water transport in the upper portion of small intestine.

Expression and immunolocalization of AQP6 in intercalated cells of the rat kidney collecting duct.

The expression and localization of AQP6 were examined in rat kidneys. In the kidney compartments, the expression was more intense in the outer medulla than in the cortex or inner medulla, and was negative in the glomerulus. During development, the AQP6 mRNA expression in the kidney was not detected in the fetus, but was recognized at birth, increased gradually by 4 weeks of age, and was unchanged thereafter. In situ hybridization demonstrated significant signals for AQP6 mRNA along the outer and inner medullary collecting ducts. Since the localization of the AQP6 mRNA-expressing cells was comparable to that of immunoreactive H+ ATPase-bearing cells in the collecting duct, they were identified as intercalated cells. No AQP6 mRNA signals were recognizable in other cells in the kidneys, including glomerular cells. No glomerular expression of AQP6 mRNA was confirmed by RT-PCR using total RNA extracted from the glomeruli. Immunohistochemistry using an antibody raised against recombinant rat AQP6 protein could localize the immunoreactivity in a population of collecting duct cells. Serial section observations indicated that the AQP6-immunoreactive cells corresponded to H+ ATPase bearing intercalated cells.

Cytokines and cell cycle regulation in the fibrous progression of crescent formation in antiglomerular basement membrane nephritis of WKY rats.

Cytokines may regulate cell proliferation by cell-cycle-regulatory proteins, in which cyclin-dependent kinase inhibitors (CDKI) inhibit cell proliferation. We investigated whether CDKI p21 or p27, both of which are potentially regulated by transforming growth factor (TGF)-beta, a key cytokine in fibrogenesis, are involved together with TGF-beta and/or platelet-derived growth factor (PDGF) in the fibrous progression of glomerular crescent formation and examined the sequential change in the cell type and the cellular background of myofibroblasts in crescent formation. Crescentic glomerulonephritis (GN) was induced by i.v. injection of rabbit antirat glomerular basement membrane antiserum in WKY rats. Animals were killed 1, 2, 3 and 4 weeks after the induction of GN, and their kidneys were processed for immunohistochemical examination. After 1 week more than 85% of glomeruli showed cellular crescents, which became fibrocellular with decreased cellularity by 4 weeks. ED 1-positive macrophages were components of crescent cells in about 44% at 1-2 weeks, and this proportion declined markedly afterwards. Alpha smooth muscle actin (alpha SMA, a marker for myofibroblasts)-positive cells were found in Bowman's epithelial cells (BEP) and in some crescent cells at 1 week, becoming major components of crescent cells by 4 weeks (about 40%). It was 2 weeks before invasion of alpha SMA-positive interstitial cells into glomeruli was evident. PDGF-B and PDGF receptor beta-positive cells, indicating possible targets for PDGF, were found in BEP adjoining crescent formation almost exclusively from 1 to 2 weeks. By contrast, both TGF-beta receptor types I- and II-positive cells, indicating possible effectors for TGF-beta, were found in BEP and crescent formation, and the percentage of these in the crescent formation did not change until 4 weeks (about 32%). Cells with positive immunostaining for proliferating cell nuclear antigen and cyclin A, markers for cell proliferation, in the crescent formation peaked in number and proportion at 1-2 weeks, then decreased. In contrast, cells with positive immunostaining for p21 and p27, CDKI, were sparse at 1 week, and then increased markedly in number and in proportion, peaking at 3 (39.6%) or 2-3 weeks (about 25-30%), respectively. The present study demonstrates that restrained expression or a transient increase in p21 and p27 may be associated with proliferation or with inhibited proliferation of crescent cells, most of which are macrophages and myofibroblasts. The action, of PDGF and TGF-beta may contribute to the recruitment of myofibroblasts into the crescent. The action of TGF-beta on crescent cells might be linked to the expression of p21 and/or p27.

Immunolocalization of aquaporin-8 in rat digestive organs and testis.

Expression of aquaporin-8 mRNA has previously been shown in hepatocytes, pancreatic acinar cells, colon epithelial cells and seminiferous tubules of the testis in the rat by in situ hybridization technique. However, immunolocalization of this water channel has not yet been demonstrated. In the present study, the localization of immunoreactive aquaporin-8 and expression of the mRNA were examined in rat organs (cerebrum, cerebellum, eye, salivary gland, heart, lung, liver, pancreas, esophagus, stomach, jejunum, ileum, colon, testis, ovary, kidney, spleen and lymphnode) by immunohistochemistry using an antibody against aquaporin-8 and ribonuclease protection assay. Aquaporin-8 was distinctly immunolocalized on the apical membranes of pancreatic acinar cells and mucosal epithelium of the colon and jejunum. In the liver, the bile canalicular membrane of hepatocytes was immunostained. In the testis, immunoreactive aquaporin-8 was demonstrated on the luminal side of the seminiferous tubules. At high magnification, the peroxidase reaction products appeared on the ramified cytoplasmic membrane of Sertoli cells surrounding the residual bodies or spermatogenic cells. Specificity of the antibody was verified by Western blot analysis showing a minor approximately 28 kDa band (deduced deglycosylated form of aquaporin-8) and a major approximately 30 kDa band (glycosylated form) in these organs. The intensity of aquaporin-8 immunoreactivity was approximately comparable to that of aquaporin-8 mRNA expression in the liver, pancreas, colon, jejunum and testis. The aquaporin-8 mRNA expression in the hepatocytes was presumed to be closely associated with the structure of bile canaliculi since the message was detected in hepatocytes immediately after isolation from the liver but not in cells following cultivation for three days. The localization of immunoreactive aquaporin-8 indicated functions for this water channel in the secretion of bile and pancreatic juice, and the secretion or absorption of water in the colon and jejunum, and the maturation or liberation of spermatogenic cells in the testis.

Phenotypic modulation of parietal epithelial cells of Bowman's capsule in culture.

The origin of cobblestone-like polygonal cells (the most numerous in renal glomerular cell culture) remains controversial; they could be either dedifferentiated podocytes or parietal epithelial cells (PECs) of Bowman's capsule. Poor cellular outgrowth from glomeruli devoid of Bowman's capsule (decapsulated glomeruli) hinders podocytes being obtained without contamination of PECs in culture. Since podocytes are easily damaged during the isolation of glomeruli by the conventional sieving method, we devised a gentle isolation method without forced sieving, resulting in substantial numbers of arborized cells growing out from decapsulated glomeruli. The cells were distinctly different from cobblestone-like polygonal cells in their irregular and often arborized shape and extended long cytoplasmic processes that often crossed over adjacent cells. The arborized cells from decapsulated glomeruli showed intense staining for a podocyte-specific marker, podocalyxin, but no staining for markers specific to PECs (pan cadherin), mesangial cells (Thy-1) or endothelial cells (von Willebrand factor, RECA-1), indicating their podocyte origin. Polygonal cells growing out from encapsulated glomeruli were negative for podocalyxin and positive for pan cadherin at the peripheral cell-cell contact. Thus, the cell population from decapsulated glomeruli is distinctly different from that from encapsulated glomeruli, supporting the idea that polygonal cells originate from PECs, although immunocytochemical markers specific to podocytes in vivo such as WT1, synaptopodin, HSP27 and P-31 antigen were expressed significantly in the polygonal cells. Occasionally, large irregular-shaped cells appeared at the periphery of the outgrowths from encapsulated glomeruli. They were similar in shape to the arborized cells from decapsulated glomeruli but were identical in antigenic properties to cobblestone-like polygonal cells and thus may be named "pseudo-arborized cells". We conclude that PECs in culture modulate their phenotype to resemble podocytes.

Expression and localization of angiogenic inhibitory factor, chondromodulin-I, in adult rat eye.

PURPOSE: To determine the role in the eye of chondromodulin (ChM)-I, which has been identified in cartilage as an angiogenic inhibitor, the expression and localization and a possible function of ChM-I were investigated. METHODS: Expression and localization of ChM-I in rat eyes were examined by RNase protection assay and in situ hybridization and by immunostaining, using an antibody against a synthetic peptide. The effect of recombinant ChM-I on tube morphogenesis of retinal endothelial cells was examined in culture. RESULTS: The rat ChM-I gene was determined to encode the open reading frame of 334 amino acid residues, and ChM-I mRNA was exclusively expressed in cartilage, eye, and cerebellum in rats. ChM-I mRNA expression was evident in the iris-ciliary body, retina, and scleral compartments, but not in other compartments of the eye. In situ hybridization revealed mRNA expression in the ganglion cells, inner nuclear layer cells, and pigment epithelium in the retina and in the nonpigment epithelium of the ciliary body. Immunoreactive ChM-I was present in these cells and also in the vitreous body. Western blot analysis detected an approximately 25-kDa band of ChM-I presumed as a secretory form in the aqueous humor and vitreous body and an approximately 37-kDa band as a precursor form in the retina. Recombinant human ChM-I inhibited tube morphogenesis of human retinal endothelial cells in vitro. CONCLUSIONS: These observations indicate a potential role for ChM-I in inhibition of angiogenesis in the rat eye.

Immunolocalization of aquaporin-9 in rat hepatocytes and Leydig cells.

The aquaporin (AQP)-9 gene was recently isolated from human and rat liver cDNA libraries as a member of the water channel family for water and neutral solutes. Although the expression of AQP9 mRNA has been demonstrated in several organs including the liver and testis by Northern blot analysis, the cellular and subcellular localization of the AQP9 protein remains unclear. In the present light and electron microscopic immunohistochemical study, the localization of the AQP9 immunoreactivity was examined in fifteen kinds of rat organs using an antibody against rat AQP9 synthetic peptide. The antibody immunostained a major band of approximately 33 kDa in the liver by Western blot analysis. Immunoreactivity for AQP9 was found exclusively in the liver and testis among the organs examined. In the liver, positive staining appeared selectively along the space of Disse. Immunoelectron microscopy confirmed the localization of AQP9 on the surface of hepatocyte microvilli facing the space of Disse. In the testis, the plasma membrane of Leydig cells located between seminiferous tubules was conspicuously immunoreactive to the antibody. Intense mRNA expression was detected in the liver and testis but not in other organs by ribonuclease protection assay. These findings suggest a specific role for AQP9 in the transport of water and non-charged solutes in hepatocytes and Leydig cells.

FAT is a component of glomerular slit diaphragms.

BACKGROUND: Slit diaphragms are intercellular junctions of podocytes of the renal glomerulus. The molecular composition of slit diaphragms is still elusive. Slit diaphragms are characterized by the presence of a wide intercellular space. The morphological feature is shared by desmosomes and adherens junctions, which contain members of the cadherin superfamily. Thus, we have hypothesized that some components of slit diaphragms belong to the cadherin superfamily. Consequently, we have isolated cDNA encoding FAT from reverse-transcribed (RT) glomerular cDNA by homology polymerase chain reaction (PCR) using primers based on conserved sequences in cadherin molecules. FAT is a novel member of the cadherin superfamily with 34 tandem cadherin-like extracellular repeats, and it closely resembles the Drosophila tumor suppressor fat. METHODS: Expression of FAT was examined in glomeruli of the adult rat kidney by the ribonuclease protection assay and in situ hybridization. To localize the FAT protein in podocytes minutely, we prepared affinity-purified antibody against FAT by immunizing rabbits against an oligopeptide corresponding to the C-terminal 20 amino acids. RESULTS: Expression of FAT mRNA was detected in total RNA from glomeruli. In situ hybridization revealed significant signals in podocytes. Western blot analysis using solubilized glomeruli showed a single band, in which the molecular weight was more than 500 kD. Immunostaining of cultured epithelial cells from rat kidney (NRK52E) revealed FAT accumulation in cell-cell contact sites. In the glomerulus, FAT staining was observed distinctly along glomerular capillary walls. Double-label immunostaining using monoclonal antibody against slit diaphragms (mAb 5-1-6) showed identical localization of anti-FAT antibody and mAb 5-1-6. Furthermore, the double-label immunogold technique with ultrathin cryosections demonstrated that gold particles for FAT cytoplasmic domain were located at the base of slit diaphragms labeled by mAb 5-1-6 and that the cytoplasmic domain of FAT colocalized with ZO-1, a cytoplasmic component associated with slit diaphragms. CONCLUSION: The molecular structure of FAT and its colocalization with 5-1-6 antigen and ZO-1 indicate that FAT is a component of slit diaphragms.

Cloning of rat nephrin: expression in developing glomeruli and in proteinuric states.

BACKGROUND: Nephrin is identified as a product of the gene mutated in a patient with congenital nephrotic syndrome of the Finnish type. However, its precise localization and function are not yet fully clarified. METHODS: To clone the rat homologue of nephrin, polymerase chain reaction (PCR) was employed. To elucidate the localization and expression of nephrin, immunohistological analysis with a specific antirat nephrin antibody, reverse transcription-PCR, and RNase protection assay were performed. RESULTS: Amino acid sequences of rat and human nephrin are highly homologous (82.2% identity). The domain structure of nephrin is also highly conserved between rats and humans. The rat nephrin was detected only in kidney glomeruli along glomerular capillary walls, and its localization was always identical to that of the anti-slit diaphragm monoclonal antibody (mAb) 5-1-6-recognized antigen in normal matured and fetal rat glomeruli and in the glomeruli of proteinuric states. The nephrin staining pattern was clearly distinguished from that of zonula occludens-1 (ZO-1), alpha3-integrin, or podocalyxin. mRNA expression for nephrin was first detected in the fetal rat kidneys at 18.5 embryonic days. Nephrin mRNA expression decreased just after injection of mAb 5-1-6 (47.4%) or puromycin aminonucleoside (51.2%), and the staining pattern of nephrin shifted from a linear to a granular pattern in both proteinuric states. CONCLUSIONS: Nephrin is localized in slit diaphragm in the matured glomeruli and is identical with mAb 5-1-6 antigen. Nephrin is involved in the development of proteinuria not only in mAb 5-1-6 nephropathy, but also in puromycin aminonucleoside nephropathy.

Expression profile of extracellular matrix and its regulatory proteins during the process of interstitial fibrosis after anti-glomerular basement membrane antibody-induced glomerular sclerosis in Sprague-Dawley rats.

Anti-glomerular basement membrane (GBM) nephritis in Sprague-Dawley (SD) rats was characterized by development of marked glomerular sclerosis and tubulointerstitial fibrosis. To elucidate sequential change of the glomerular sclerosis and tubulointerstitial fibrosis, accumulation and mRNA expression of extracellular matrix (ECM) components and transforming growth factor (TGF)-beta were examined in the glomerulus and cortex during the disease course by histology, immunostaining and ribonuclease protection assay. Mild proliferative and degenerative lesions appeared in the glomeruli by day 15 after anti-GBM antibody binding to GBM and progressed to glomerular sclerotic lesion thereafter. Conversely, interstitial change was first recognized by infiltration of mononuclear cells after day 20, followed by marked accumulation of ECM and tubular degeneration. The interstitial fibrosis was induced without apparent binding of anti-GBM antibody to tubular basement membrane. Accumulation of fibronectin, collagen type I and type IV was noted in the interstitium by immunofluorescence microscopy in association with enhanced expression of mRNA for these ECM components and their regulatory molecules such as matrix metalloproteinase (MMP2), tissue inhibitor of metalloproteinase (TIMP)-1 and TGF-beta1 both in glomeruli and cortex. The glomerular expression of these mRNA increased apparently by day 15 and reached a plateau or a peak at day 20. The expression of the same mRNA increased gradually from day 15 to day 29 in the cortex. These observations show that interstitial fibrosis follows glomerular sclerosis after anti-GBM antibody injection in SD rats, suggesting that at least a part of the mechanism for ECM accumulation in the glomerulus and interstitium is essentially the same in terms of composition of ECM and expression of its regulatory molecules.

Origin of hyperplastic epithelial cells in idiopathic collapsing glomerulopathy.

AIMS: Glomerular epithelial cell hypertrophy and hyperplasia are listed as the primary criteria for the diagnosis of collapsing glomerulopathy (CG), a distinct variant of focal segmental glomerulosclerosis. However, the extent of podocyte phenotypic alterations that occur in CG, and the origin of the hyperplastic epithelial cells remain to be established. METHODS AND RESULTS: Renal biopsy materials from seven out of three patients with CG were studied by serial section analysis for immunohistochemistry and electron microscopy. Markers for podocytes (PHM5 and synaptopodin), parietal epithelial cells (PECs: cytokeratin) and macrophages (CD68) were used for the immunohistochemistry. Multiple ultrathin sections from a total of 15 glomeruli, including some from patients with CG, were examined by electron microscopy. Glomerular adhesions occurred in 71% of the serially sectioned glomeruli taken from patients with CG. Hyperplastic epithelial cells were immunonegative for podocyte markers and CD68, but invariably immunopositive for cytokeratin. Electron microscopy revealed that detachment of the podocytes from involved glomerular capillary walls was extensive. Many of the detached podocytes appeared to be necrotic and apoptotic. In contrast, junctional complexes of desmosomes and zonula adherens connected hyperplastic epithelial cells to each other. Cilia were also often observed. CONCLUSIONS: The results of our ultrastructural and immunohistochemical study suggest that the hyperplastic epithelial cells observed in cases of CG are derived from PECs. Our results raise the possibility that PECs play a general role in covering glomerular tufts from which the podocytes have disappeared.

Identification of renal podocytes in multiple species: higher vertebrates are vimentin positive/lower vertebrates are desmin positive.

We sought to characterize podocytes in the kidneys of numerous species from amphibians to mammals because of the pivotal function of these cells in renal diseases. For this purpose, intermediate filament (IF) proteins of podocytes were examined by immunofluorescence microscopy using antibodies against vimentin, cytokeratins, and desmin. These staining patterns were then compared to those of parietal cells of Bowman's capsule and tubular cells of the first portion of the proximal tubule from the same sources. As a result, podocytes from mammals (rat, rabbit, dog, cow, and human) and birds (chicken) showed intense vimentin staining without exception, but rarely staining for cytokeratins or desmin. Parietal cells from all these animals were highly heterogeneous with respect to cytokeratin or vimentin staining. Of the tubular cells, only those from humans and chickens were reactive and then only with anti-cytokeratin antibodies. In the reptiles (Chrysemys scripta elegans, Chinemys reeveri, Elaphe quadrivirgata, and Anolis carolinensis), podocytes and other epithelial cells were positive for cytokeratins. Vimentin staining differed among the species, but was not characteristic for podocytes. Anti-desmin antibody reacted strongly only with podocytes from Anolis. In amphibians (Rana catesbeiana and Xenopus laevis), anti-desmin antibody stained podocytes more intensely than any other cell. Cytokeratin and vimentin staining did not differentiate podocytes from the other cell types. These findings indicate that podocytes are characterized by intense vimentin staining in the higher vertebrates and by desmin staining in the lower vertebrates denoting potentially distinctive physiological functions of IF proteins in podocytes from each of these groups.

Expression and localization of aquaporins in rat gastrointestinal tract.

A family of water-selective channels, aquaporins (AQP), has been demonstrated in various organs and tissues. However, the localization and expression of the AQP family members in the gastrointestinal tract have not been entirely elucidated. This study aimed to demonstrate the expression and distribution of several types of the AQP family and to speculate on their role in water transport in the rat gastrointestinal tract. By RNase protection assay, expression of AQP1-5 and AQP8 was examined in various portions through the gastrointestinal tract. AQP1 and AQP3 mRNAs were diffusely expressed from esophagus to colon, and their expression was relatively intense in the small intestine and colon. In contrast, AQP4 mRNA was selectively expressed in the stomach and small intestine and AQP8 mRNA in the jejunum and colon. Immunohistochemistry and in situ hybridization demonstrated cellular localization of these AQP in these portions. AQP1 was localized on endothelial cells of lymphatic vessels in the submucosa and lamina propria throughout the gastrointestinal tract. AQP3 was detected on the circumferential plasma membranes of stratified squamous epithelial cells in the esophagus and basolateral membranes of cardiac gland epithelia in the lower stomach and of surface columnar epithelia in the colon. However, AQP3 was not apparently detected in the small intestine. AQP4 was present on the basolateral membrane of the parietal cells in the lower stomach and selectively in the basolateral membranes of deep intestinal gland cells in the small intestine. AQP8 mRNA expression was demonstrated in the absorptive columnar epithelial cells of the jejunum and colon by in situ hybridization. These findings may indicate that water crosses the epithelial layer through these water channels, suggesting a possible role of the transcellular route for water intake or outlet in the gastrointestinal tract.

Localization and expression of AQP5 in cornea, serous salivary glands, and pulmonary epithelial cells.

Aquaporin (AQP) 5 gene was recently isolated from salivary gland and identified as a member of the AQP family. The mRNA expression and localization have been examined in several organs. The present study was focused on elucidation of AQP5 expression and localization in the eye, salivary gland, and lung in rat. RNase protection assay confirmed intense expression of AQP5 mRNA in these organs but negligible expression in other organs. To examine the mRNA expression sites in the eye, several portions were microdissected for total RNA isolation. AQP5 mRNA was enriched in cornea but not in other portions (retina, lens, iris/ciliary body, conjunctiva, or sclera). AQP5 was selectively localized on the surface of corneal epithelium in the eye by immunohistochemistry and immunoelectron microscopy using an affinity-purified anti-AQP5 antibody. AQP5 was also localized on apical membranes of acinar cells in the lacrimal gland and on the microvilli protruding into intracellular secretory canaliculi of the serous salivary gland. In the lung, apical membranes of type I pulmonary epithelial cells were also immunostained with the antibody. These findings suggest a role of AQP5 in water transport to prevent dehydration or to secrete watery products in these tissues.

Involvement of R-cadherin in the early stage of glomerulogenesis.

The earliest commitment to the formation of glomeruli is recognizable in S-shaped bodies. Although cell-cell adhesion seems likely to play a crucial role in this process, how glomerular epithelial cells segregate from the other parts of the nephron is unknown. In this study, immunofluorescence microscopy and monoclonal antibodies specific for mouse R-, E-, P- and N-cadherins were used to examine which of these adhesion molecules are involved in glomerulogenesis of the mouse kidney. Weak R-cadherin staining was first found in the vesicle stage, becoming restricted to glomerular visceral epithelial cells (VEC) during the S-shaped body stage. The intensity of this staining became stronger in the capillary loop stage, whereas parietal epithelial cells (PEC) and tubular cells did not stain. In the maturing stage, VEC gradually lost their staining for R-cadherin. E-cadherin was detected in ureteric buds and the upper limb of S-shaped bodies. From the capillary loop to the maturing stage, anti-E-cadherin stained epithelial cells in all tubule segments, but no label was seen in VEC or PEC. P-cadherin was also stained in the ureteric buds and in the upper limb of S-shaped bodies. N-Cadherin was weakly stained in cells at the vesicle stage, but thereafter staining of N-cadherin was not detected at any stage of glomerular formation. Immunoelectron microscopy of differentiating VEC was performed using antibodies specific to alpha-catenin, which is associated with cadherin. Subsequently, immunogold particles identifying alpha-catenin were localized on junctions between primary processes of VEC. These findings indicate that R-cadherin is uniquely expressed in differentiating VEC, suggesting an important role in the early stages of glomerulogenesis.

Thyroid hormone regulates expression of shaker-related potassium channel mRNA in rat heart.

Effects of thyroid hormones on cardiac function or rhythm have been known; however, the mechanism is still unclear. In the present study examined were effects of triiodethyronine (T3) on voltage-gated potassium channel gene expression in rat heart since the potassium channels were presumed to modulate cardiac functions. The mRNA expression of five voltage-gated potassium channel gene alpha subunits (Kv1.2, Kv1.4, Kv1.5, Kv2.1, and Kv4.2) in heart was examined by ribonuclease protection assay in rats which were treated with T3 or propylthyouracil (PTU). All these genes except Kv1.4 mRNA were apparently expressed in the normal rat heart ventricle. Kv1.2 mRNA expression in ventricle was markedly suppressed by T3-treatment and enhanced by PTU-treatment. Interestingly, upregulation of Kv1.4 mRNA expression and downregulation of Kv1.5 mRNA expression were concomitantly induced in the ventricle by the PTU-treatment. In addition, the downregulation of the ventricular Kv1.5 mRNA expression induced by PTU was restored by T3 replacement. No changes of Kv2.1 and Kv4.2 mRNA expression were observed in the ventricles by the T3- or PTU-treatment. In heart atrium the same findings were observed. Kv1.4 mRNA expression, which was detectable in control rat atrium, also decreased significantly by T3-treatment. In contrast, no changes of Kv1.2, Kv1.4, and Kv1.5 mRNA expression in rat brains were induced by T3-treatment. These findings suggest that thyroid hormone specifically influences mRNA expression of Shaker-related potassium channel genes in rat hearts through a common T3 receptor-mediated regulation at a transcriptional level.

Expression and localization of cyclooxygenase isoforms and cytosolic phospholipase A2 in anti-Thy-1 glomerulonephritis.

Glomerular expression of the major rate-limiting enzymes for prostanoid synthesis, cyclooxygenase isoforms (COX-1 and COX-2) and cytosolic phospholipase A2 (cPLA2), was investigated in anti-Thy-1 nephritis in rats. Ribonuclease protection assay demonstrated minimal COX-1 mRNA expression in glomeruli of control rat kidneys and a gradual increase of expression from day 1 to day 10 after administration of monoclonal anti-rat Thy-1 antibody. On the other hand, COX-2 mRNA expression, also minimal in the normal glomeruli, was enhanced in a biphasic pattern with two peaks at 1 h and day 10. Expression of cPLA2 mRNA, which was undetectable in normal glomeruli, was induced on day 1 and increased gradually in a pattern similar to that of COX-1 mRNA expression. Immunofluorescence microscopy, using antibodies against COX isoforms, showed that both COX-1 and COX-2 were negligible or faintly detectable in the glomeruli of control rat kidneys. In contrast, the immunofluorescence for COX-1 was intensified on days 4 and 10 along the glomerular capillary walls probably in glomerular epithelial and/or endothelial cells, whereas COX-2 staining was exclusively enhanced in the glomerular epithelial cells at 1 h and day 10 during the course of anti-Thy-1 nephritis. These findings indicate that prostanoids generated through induction of COX-1, COX-2, and cPLA2 are implicated in the mediation of the mesangial cell injury model. In particular, the upregulation of COX-2 expression in glomerular epithelial cells in the selective mesangial cell injury model suggests an intercellular interaction between mesangial cells, and glomerular epithelial cells.