猪肾小球内皮细胞与系膜细胞的发育过程及相互关系

目的:明确中国实验用小型猪肾小球内皮细胞与系膜细胞的发育过程及相互关系。方法:采集不同时间点(胚胎28～112d及出生后1d、7d、14d、21d)中国实验用小型猪肾组织,应用免疫荧光技术检测胚肾发育不同阶段(帽状间充质、肾小囊体、逗号形体、"S"形体、毛细血管袢期肾小球及成熟肾小球)内皮细胞标志物CD31与系膜细胞标志物α-SMA的表达情况。结果:内皮细胞标志物CD31在胚肾早期呈散在性分布,继而围绕肾小囊体和逗号形体呈"环抱"状分布,然后进入"S"形体下端的血管裂隙内聚集形成无管腔的"前毛细血管束",最后表达于成熟肾小球毛细血管内皮细胞。系膜细胞标志物α-SMA在早期胚肾、肾小囊体和逗号形体阶段均无表达;"S"形体早期分布于"S"形体周围,后期进入"S"形体下端的血管裂隙;毛细血管袢期聚集在肾小球血管极根部;随着肾小球发育逐渐向肾小球内延伸,最终表达于成熟肾小球系膜区。CD31与α-SMA双重染色的结果显示,在毛细血管袢期CD31阳性的内皮细胞聚集形成无管腔的前毛细血管束,而α-SMA阳性的系膜细胞聚集在肾小球血管极的根部;随着肾小球发育,α-SMA阳性的系膜细胞逐渐由血管极根部向肾小球内迁移,同时CD31阳性的内皮细胞逐渐形成带有管腔的毛细血管丛。结论:中国实验用小型猪肾小球内皮细胞的发育开始于后肾间充质阶段,系膜细胞的发育开始于"S"形体阶段,即肾小球系膜细胞发育在内皮细胞之后;在肾小球血管丛形成过程中,内皮细胞与系膜细胞间可能存在重要的相互作用。     

The glomerular mesangium: uptake and transport of intravenously injected colloidal carbon in rats.

Collodial carbon, 70 mg/100 g, was injected into rats which were sacificed for histologic study of the kidneys at intervals of five minutes to seven weeks. Transient thrombocytopenia and albuminuria were observed. Uptake of carbon by the mesangium of glomeruli was maximal at 32 hr and gradually decreased thereafter. Semiquantitative analysis of the distribution of carbon particles within glomeruli revealed a predominately peripheral localization during early time periods, and increased relative concentration of particles within more central zones and in the lacis area at the vascular pole of the glomerulus at two to seven weeks, indicating that one of the mechanisms for clearance of materials from the mesangium was movement of particles in the direction of the lacis area. Sequential electron microscopic studies showed that carbon particles moved through fenestrae in the endothelium covering the mesangium into channels between mesangial cells. Observations at later intervals suggested that carbon eventually reached the vascular pole by being passed on from one mesangial cell to the next. Vasoactive amines or other substances derived from platelets may play an important role in initiating the process of mesangial uptake.     

Effect of mesangial cell lysis and proliferation on glomerular hemodynamics in the rat.

To elucidate an involvement of mesangial cells in the regulation of glomerular hemodynamics, renal micropuncture techniques and glomerular morphometry were employed in Munich-Wistar rats with mesangial cell lytic or proliferative lesions induced by administration of an antibody reactive with Thy-1.1-like antigens on the mesangial cell surface. The antibody-induced mesangial cell lysis at day 1 resulted in a significant decrease in glomerular ultrafiltration coefficient, leading to reduction in single nephron glomerular filtration rate (SNGFR) in spite of a significant increase in both glomerular hydrostatic pressure and single nephron plasma flow (SNPF). During the antibody-induced proliferative lesion at day 6, glomerular ultrafiltration coefficient and SNGFR remained reduced; however, SNPF was now decreased. Morphometric analysis showed the enlargement of capillary luminal volume and the development of new open space in the mesangium accessible for blood flow in the mesangial cell-lytic glomeruli at day 1. An increase in mesangial cell volume was found in the proliferative glomeruli at day 6. The total area of peripheral glomerular basement membrane, presumed as the probable filtration area, was unchanged in these glomeruli. These results indicate that mesangial lesions decrease glomerular ultrafiltration coefficient, and suggest that mesangial cells participate in regulation of glomerular filtration rate.     

Leprecan distribution in the developing and adult kidney

The temporal and spatial deposition of extracellular matrix proteins is critical for nephrogenesis and glomerular maturation. We previously characterized leprecan as a novel chondroitin sulfate proteoglycan which has been recently shown to have prolyl hydroxylase activity. In this study, we examine the distribution of leprecan during nephrogenesis and after a hypertrophic stimulus to the adult kidney. During development, leprecan was localized to mesenchymal aggregates, early comma- and S-phase structures as determined by immunohistochemistry and in situ hybridization. Leprecan mRNA was increased in cells around the vascular cleft of the S- and comma-phase glomeruli. Expression was found in podocytes, mesangial cells, and parietal epithelial cells of loop-phase glomeruli. Leprecan mRNA was substantially decreased in the glomeruli of the adult kidney compared to the developing kidney with a uniform distribution between the glomeruli and the tubules. Within adult glomeruli, leprecan was found in the mesangium mesangial matrix, podocytes, and in Bowman's capsule. In response to glomerular hypertrophy, produced by unilateral nephrectomy, leprecan synthesis was increased in the adult kidney. We suggest that the regulated expression of leprecan during glomerular development or hypertrophy coupled with its reported prolyl hydroxylase activity plays a role during basement membrane assembly.     

Elastic fiber proteins in the glomerular mesangium in vivo and in cell culture

BACKGROUND: Glomerular capillaries of the mammalian kidney are exposed to high intraluminal hydrostatic pressures and require elastic constraint to maintain size, shape, and integrity. Previous morphological and functional studies indicated that the extracellular matrices of glomeruli, that is, basement membrane and mesangial matrix, contribute to glomerular resilience and mechanical stability. Immunofluorescence microscopy findings demonstrated elastic fiber components to be located in the renal vasculature, including glomeruli. The aim of this study was to clarify the exact glomerular localization, composition, and cellular production of these proteins. METHODS: We examined the renal distribution of the elastic fiber proteins fibrillin-1, emilin, microfibril-associated glycoproteins (MAGPs) 1 and 2, latent transforming growth factor-binding protein-1 (LTBP-1), and elastin using immunohistology and immunoelectron microscopy of human, rat, and mouse kidneys. In mesangial cell cultures, we also studied the expression and extracellular deposition of such proteins by use of Northern blotting and immunocytochemistry. RESULTS: Fibrillin-1, emilin, MAGPs 1 and 2, and LTBP-1 were present in glomeruli of mouse, rat, and human kidney, where they were located predominantly in the mesangial extracellular matrix underlying glomerular endothelium and basement membrane. Several of these proteins, as well as elastin, were also expressed in the renal vasculature. While elastin localized to the glomerular vascular pole in afferent and efferent arterioles extending to Bowman's capsule, it was not found in the glomerular capillary tuft. Cultured mesangial cells of rat, mouse, and human kidneys expressed mRNAs of fibrillin-1, emilin, MAGP-2, and elastin, and the respective proteins localized within and outside of mesangial cells, as shown by immunocytochemistry. mRNA expression of fibrillin-1, emilin, and elastin was strong in quiescent mesangial cells; their gene expression was further up-regulated by transforming growth factor-beta1, while it was transiently reduced when cells were exposed to mitogenic 10% fetal calf serum and platelet-derived growth factor. CONCLUSIONS: These findings demonstrate that specific elastic fiber proteins are produced and secreted by mesangial cells. This process is regulated by growth factors. Their abundance in the extracellular matrix of the mesangium is in keeping with the concept that elastic fiber proteins contribute to the mechanical stability and elastic strength of the glomerular capillary tuft.     

Influence of Coxsackie B4 virus on uptake and transport of colloidal carbon by glomerular mesangium

To evaluate the influence of Coxsackie B4 virus (Cox. B4 virus) on the clearing function of the mesangium, colloidal carbon and Cox. B4 virus were intravenously injected into five groups of female Swiss albino mice. Group I received carbon and no Cox. B4 virus; group II, carbon and live Cox. B4 virus; and group III, carbon and inactivated Cox. B4 virus; Group IV and V received live and inactivated Cox. B4 virus, respectively, first, followed by carbon. Semiquantitative analysis of the distribution of carbon particles within glomeruli revealed that in groups II and III disappearance of intracapillary carbon particles was delayed significantly, and that in group II mesangial transport of carbon particles in the direction of the vascular pole of the glomerulus was suppressed. In Groups IV and V, when the interval between carbon and virus injections was shorter than 24 hours, many carbon particles were observed within glomerular capillary lumina compared with Group I. The mechanism of suppressed mesangial uptake of carbon particles may be explained by change of the charge barrier of the glomerular capillary walls and the expansion of the subendothelial space observed after Cox. B4 virus injection. The suppressed mesangial transport of macromolecules appears to be intimately related to be effect of substances produced in viremia and to impairment by viral infection of the function of mononuclear cells infiltrating glomeruli. These results suggest that mesangial uptake and transport of carbon particles are suppressed in transient glomerular changes due to direct injury by the live virus. This means that the biologic property of Cox. B4 virus may be a very important determinant of the clearing function of the mesangium.     

Mesangial cells and their adhesive properties

Glomerular mesangial cells play a central role in maintaining structure and function of the glomerular capillary ultrafiltration apparatus. Under physiological and pathological conditions, mesangial cells regulate amount and composition of the surrounding extracellular matrix. Conversely, components of the embedding matrix affect the mesangial cell phenotype. These interactions are mediated via specific cell surface receptors, the best studied group of which is the beta1 integrin family. The beta1 integrins play a role in mesangial cell adhesion, migration, survival and proliferation. Expression and abundance of integrins in healthy and diseased glomeruli and their functions and mediation of signals are discussed in this review. Other factors modulating mesangial cell-matrix interactions, such as antiadhesive proteins, cytokines, disintegrins and nitric oxide, are also considered. The available evidence from in vitro and in vivo studies indicates that receptor-mediated interactions between mesangial cells and the normal or abnormal extracellular matrix regulate the mesangial cell phenotype and thus contribute to normal maintenance of the glomerulus and to remodeling and repair of the glomerular capillary tuft in response to injury.     

Local actions of endogenous angiotensin II in injured glomeruli

A previous study showed that exogenous angiotensin II (AngII) induces proliferation of glomerular cells through systemic actions of AngII. In the present study, the authors examined the mode of actions of endogenous AngII in injured kidneys that were made deficient in AT1 by using in vivo transfection of antisense oligodeoxynucleotide (AS-ODN). Thy-1 nephritis was induced in rats by injection of mAb 1-22-3. Four days later, glomerular transfection was performed by unilateral whole-kidney electroporation after AT1 AS-ODN delivery through the left renal artery (n = 7). The expression of renal AT1 was assessed by autoradiography. The effect of the AS-ODN transfection was assessed 3 d later and compared with transfection with control ODN (n = 6), systemically administered pharmacologic AT1 antagonist losartan (n = 5) as well as untreated Thy-1 animals (n = 5). Fluorescence-labeled AS-ODN was found transfected in almost all glomeruli and localized primarily to the mesangium. Compared with the contralateral untransfected kidney in both normal and Thy-1 rats, AS-ODN suppressed cortical AT1 expression by some 70%. The AS-ODN transfected kidneys of Thy-1 rats had significantly lower glomerular mesangial cell proliferation (7.38 +/- 0.68 cells/glomerulus) and extracellular matrix accumulation (0.262 +/- 0.009) than kidneys transfected with control ODN (10.94 +/- 0.51 cells/glomerulus and 0.342 +/- 0.031), contralateral untransfected kidneys (9.56 +/- 1.01 cells/glomerulus and 0.371 +/- 0.011), or kidneys that were exposed to Thy-1 alone (10.45 +/- 1.06 cells/glomerulus and 0.359 +/- 0.013). There were no significant differences in systolic BP among groups. In glomeruli, immunohistochemistry detected no difference in AT2 receptor expression, number of ED1-positive macrophages or number of apoptotic cells among groups. Thus, in renal injury induced by Thy-1 nephritis, selective suppression of mesangial AT1 expression by AS-ODN significantly reduced mesangial cell proliferation and matrix. These data provide in vivo evidence that injured glomeruli are sensitive to local tissue actions of AngII, which promote proliferation and matrix accumulation within the glomerulus.     

An overlapping syndrome of IgA nephropathy and membranous nephropathy?

This is the first report of primary glomerular disease with both mesangial IgA and subepithelial IgG deposits in the glomeruli at the same time. This nephropathy, discovered in 3 patients, is either a new disease entity or an overlapping of IgA nephropathy and membranous nephropathy. Follow-up studies may clarify the pathogenesis of IgA nephropathy and/or membranous nephropathy. In 1 patient the clinical findings resembled those of IgA nephropathy, and in the other 2 they were those of membranous nephropathy. Light microscopy showed generalized diffuse increases in mesangial cells and matrix, and there was slight capillary wall thickening. In the glomeruli, immunofluorescence microscopy demonstrated both granular deposits of IgA in the mesangium and granular deposits of IgG along the capillary loops. On electron microscopy, electron-dense deposits were identified not only in the mesangium but also on the epithelial side of the glomerular basement membrane. These findings were confirmed by the immunoperoxidase technique in electron-microscopic studies of these antibody classes. These glomeruli contained both the dense reaction products of IgA deposits in the paramesangium and mesangial matrix and the dense reaction products of IgG deposits on the epithelial side of the basement membrane.     

Expression of a monoclonal antibody (3G5) defined ganglioside antigen in the renal cortex.

The monoclonal antibody (mAb) 3G5 was found, by indirect immunofluorescence, to bind to renal cortical structures in frozen sections of human, rat and calf kidneys. Double indirect immunofluorescence studies on frozen sections of rat kidneys showed that 3G5 stained only the glomerulus and the distribution of the 3G5 antigen on the glomerulus was more extensive than the staining observed with antibodies to Factor VIII antigen. 3G5 stained the proximal convoluted tubules and collecting tubules in bovine renal sections but glomeruli did not stain with 3G5. The 3G5 mAb did not stain tissue cultured bovine glomerular endothelial cells or mesangial cells, but did stain bovine glomerular epithelial cell cultures. 3G5 did not stain MDCK cell cultures. The binding of mAb 3G5 to glomeruli was investigated by immunoelectron microscopy of rat renal tissue. In contrast to the podocyte specificity on bovine glomerular cells in vitro, it was found that the specificity of 3G5 expression on rat glomerular cells in vivo was broader. No binding of mAb 3G5 was found outside the glomerulus in the rat renal cortex. Podocytes, endothelial cells and capsular epithelial cells expressed the 3G5 antigen most strongly. A lesser amount of binding was found in the glomerular basement membrane. The mesangium showed a little binding of mAb 3G5 and no binding at all was found to other cortical structures. The 3G5 antigen in rat renal tissue was found to be a glycolipid that migrated between the ganglioside markers GM2 and GM1 by immunostaining of thin layer chromatograms.(ABSTRACT TRUNCATED AT 250 WORDS)     

Changes in glomerular mesangium in kidneys with congenital nephrotic syndrome of the Finnish type

Congenital nephrotic syndrome of the Finnish type (NPHS1, CNF) is an autosomal recessive disease caused by mutations in a major podocyte protein, nephrin. NPHS1 is associated with heavy proteinuria and the development of glomerular scarring. We studied the cellular and molecular changes affecting the glomerular mesangium in NPHS1 kidneys. Marked hyperplasia of mesangial cells (MC) was mainly responsible for the early mesangial expansion in NPHS1 glomeruli. The levels of the proliferation marker, mindbomb homolog 1 and the major MC mitogen, platelet-derived growth factor, and its receptors, however, were quite normal. Only a small number of cells were positive for CD68 (marker for phagocytic cells) and CD34 (marker for mesenchymal precursor cells) in the NPHS1 mesangium. MCs strongly expressed α-smooth muscle actin, indicating myofibloblast transformation. The expression levels of the profibrotic mediators osteopontin and transforming growth factor β were up-regulated in NPHS1 glomeruli by 3.2 and 1.6-fold, respectively, compared to the controls. The synthesis by MCs of the typical fibroblast products collagen I, fibronectin, and tenascin, however, was low, and the extracellular matrix increase was caused by the accumulation of a normal MC product, collagen IV. The results indicate that severe glomerular sclerosis can develop without major qualitative cellular or molecular changes in the mesangium.     

An immunohistochemical study of developing glomeruli in human fetal kidneys

BACKGROUND: In the glomerulonephritis, mesenchymal cells frequently repeat the expression of fetal immunohistochemical phenotypes. However, in human glomerulogenesis the phenotypic alteration of mesangial and other types of glomerular cells has not been clearly defined. Our aim was to clarify the characteristics of fetal mesangial cells and glomerular capillary endothelial cells, as well as their changes during glomerulogenesis using immunohistochemistry. METHODS: We examined the renal tissues of 34 autopsied fetuses and neonates, 5 children, and 5 adults using immunohistochemistry and immunoelectron microscopy, using antibodies for cytoskeletons, contraction-associated proteins, and endothelial cell markers. RESULTS: In the V and S stages, there were no cells showing mesangial and endothelial features within the vesicles and the S-shaped bodies. In the S stage, small blood vessels, consisting of endothelial cells (CD31+, CD34+) and primitive perivascular mesenchymal cells (alpha-smooth muscle actin+, low molecular caldesmon+, vimentin+), were branched from developing interlobular arteries and appeared to extend to the lower clefts of the S-shaped bodies. In the C stage, the perivascular mesenchymal cells aggregated at the root of the immature glomeruli. In the M stage, they migrated toward the periphery of immature glomeruli and gradually lost their fetal immunohistochemical features. Similarly, with further maturation, the fetal glomerular capillary endothelial cells gradually lost the immunostaining for CD34, while the strong staining intensity of CD31 remained unchanged, just as that in the adult glomerular capillary endothelial cells. CONCLUSIONS: In human glomerulogenesis, we demonstrate that fetal mesangial and capillary endothelial cells change their immunohistochemical phenotypes with maturation. They gradually lose fetal immunohistochemical phenotypes. Already before birth, the mesangial cells in almost all glomeruli at the late M stage acquire the adult phenotype.     

Immunoelectron microscopic demonstration of Thy-1 antigen on the surfaces of mesangial cells in the rat glomerulus

Mesangial cells of F344 rats degenerated and then disappeared within 2 days after the intravenous administration of rabbit antirat thymocyte serum (ATS). Rabbit IgG and rat C3 were identified in the mesangium in the rat glomeruli. To establish the glomerular binding site of ATS administered intravenously into rats, one kidney of each rat given ATS intravenously 12 h earlier was perfused ex vivo through the renal artery with peroxidase-labeled antirabbit IgG followed by sequential glutaraldehyde and diaminobenzidine perfusions to minimize the ultrastructural damage. The other kidney was removed before the perfusion for histologic study to examine the glomerular injury. The rabbit IgG identified by peroxidase-reaction product was present diffusely in the glomerular mesangium when viewed by light microscopy and exclusively on the surfaces of most mesangial cells by electron microscopy. Immunofluorescence microscopy showed rabbit IgG essentially in the mesangium, and electron microscopy revealed the degeneration of mesangial cells in the kidneys that had been removed before the surgical perfusion. However, no histological abnormalities were found in the kidneys from control rats given ATS absorbed with rat thymocytes. The present study showed that the intravenous administration of ATS into rats induced the extensive mesangial cell damage by the binding of ATS to Thy-1 antigens on the mesangial cells.     

Cellular receptors for matrix proteins in normal human kidney and human mesangial cells

In the present study we evaluated the distribution of cell adhesion molecules, referred as very late antigens (VLA), in the normal human kidney and in mesangial cells in culture (MC). In addition, we assessed the functional properties of VLA proteins on MC. Normal human kidney and MC were stained by immunoperoxidase with mouse monoclonal antibodies to VLA proteins. We demonstrated that VLA-3, a protein that binds FN, laminin and collagen, is the predominant VLA protein in the human glomerulus and on MC. VLA-3 is located in the mesangium and on the glomerular visceral epithelial cell and endothelial cell surfaces in contact with the glomerular basement membrane. VLA-1 was demonstrated in the glomerular mesangium and VLA-5, an FN specific receptor, was present in the mesangium on glomerular endothelial cells and on MC. VLA-2 and VLA-4 were not present in the normal glomerulus nor on MC. In functional studies we evaluated the binding of MC to FN coated surfaces and the binding and phagocytosis of FN coated fluorescent beads by MC. We showed that MC bind to FN coated surfaces and that the binding is inhibited by anti-FN antibodies, EDTA and peptides containing the amino acid sequence Arg-Gly-Asp (RGD). In addition, anti-VLA-5 but not anti-VLA-3 antibodies inhibited significantly the binding of MC to FN, MC demonstrated binding and phagocytosis of FN coated beads and, purified FN inhibited both phenomena. By affinity chromatography and immunoprecipitation we demonstrated that MC FN binding proteins and MC VLA proteins are composed of two distinct protein chains that have Mr characteristics similar to those of normal human fibroblasts VLA proteins. In conclusion, the glomerular distribution of VLA-3 suggests that this protein is primarily involved on the adhesion of glomerular cells to basement membranes and matrix. MC FN receptors (VLA-5) mediate the binding of MC to FN and could mediate the phagocytosis of FN coated antigen or immune complexes by mesangial cells.     

Endothelial cell apoptosis during glomerular capillary lumen formation in vivo

Transforming growth factor-beta (TGF-beta) stimulates endothelial cell apoptosis in vitro, and inhibition of TGF-beta1 leads to retention of undifferentiated endothelial cells in developing glomerular capillaries and reduced lumen formation in vivo. This study explored the question whether glomerular capillary lumen formation in vivo may involve TGF-beta1-dependent endothelial cell apoptosis. Neutralizing anti-TGF-beta1 or non-immune IgY were infused into the renal arteries of 3-d-old rats, and the kidneys were examined 2 d later. By transmission electron microscopy, endocapillary apoptotic cells were observed at a frequency of 0.10/loop in immature glomeruli of 3-d-old rat pups. In 5-d-old rat pups given neutralizing TGF-beta1 antibody or control IgY, the frequency of endocapillary apoptotic cells was 0.03 and 0.09/loop, respectively (P < 0.001, chi(2)). Dual labeling with TUNEL and anti-von Willebrand factor (vWF) antibody showed that apoptotic cells in immature glomeruli of 5-d-old rat pups are endothelial cells. Quantitative analysis showed significantly fewer TUNEL/vWF-labeled cells in glomeruli after anti-TGF-beta1 antibody infusion than in controls. No endocapillary apoptotic cells were observed in any group in C-shaped or S-shaped bodies, and the TUNEL assay revealed no glomerular apoptotic cells in kidneys from mature rats. These findings suggest that superfluous endothelial cells are cleared from immature glomerular capillaries by apoptosis, a process regulated by TGF-beta1. Taken together with the previous finding, that TGF-beta1 blockade blunts glomerular capillary lumen formation in vivo, it is proposed that TGF-beta1-dependent apoptosis serves to open capillary lumens in this vascular bed during glomerular development.     

Glomerulonephritis associated with hepatitis B surface antigenemia. Report of a case with features of both membranous and IgA nephropathy

A 40-year-old man with hepatitis B surface (HBs) antigenemia developed the nephrotic syndrome. Renal biopsy revealed a glomerulonephritis with features of both membranous glomerulonephropathy and IgA nephropathy. Histologically some glomeruli showed mesangial expansion and hypercellularity only, while others contained sclerotic segments. Direct immunofluorescence demonstrated granular IgG-bearing deposits along the peripheral glomerular capillaries and IgA-containing ones in the mesangium. HBs antigen was detected by indirect immunofluorescence both along the glomerular capillary walls and within the mesangium. Granular epimembranous and mesangial deposits were observed by electron microscopy. A few mesangial deposits consisted of spherical particles, 35-100 nm in diameter. Although 3 cases of mixed membranous and IgA nephropathy have been previously reported, this appears to be the first one to be associated with HBs antigenemia.     

Localization of decay accelerating factor in normal and diseased kidneys

Decay accelerating factor (DAF) is a cell membrane associated glycoprotein that inhibits C3 activation. In the present study we evaluated the presence of DAF in normal (N = 15) and diseased human kidneys (N = 76). Sections of frozen tissue were stained for DAF by immunoperoxidase, utilizing three mouse monoclonal anti-DAF anti-bodies. In normal kidneys, DAF was localized in the glomerular vascular pole, apparently in the juxtaglomerular apparatus (JGA). All other structures were negative for DAF. By contrast, in diseased kidneys, two types of abnormalities were detected. First, JGA-DAF was significantly decreased and this abnormality correlated with the pathologic diagnosis and with the presence of C3, IgM and/or fibrinogen in the glomeruli. Second, DAF was present in the glomerular mesangium (67%), renal interstitium (68%) and/or blood vessels (38%). The presence of DAF in the mesangium and interstitium of the kidney correlated with each other and correlated with C1q and C3 deposition in the glomerulus. Finally, vascular DAF was significantly more common in patients with electron dense deposits in the glomeruli. In summary, DAF is present in the normal kidney and is located exclusively in the glomerular vascular pole. In diseased kidneys, DAF tends to be lost from the JGA but is often present in glomerular mesangium, interstitium and blood vessels. This pattern is specially prominent in patients demonstrating complement deposition in the glomerulus. We speculate that kidney DAF may play a role in protecting the kidney against the products of complement activation.     

Differential expression of the intermediate filament protein nestin during renal development and its localization in adult podocytes

Nestin, an intermediate filament protein, is widely used as stem cell marker. Nestin has been shown to interact with other cytoskeleton proteins, suggesting a role in regulating cellular cytoskeletal structure. These studies examined renal nestin localization and developmental expression in mice. In developing kidney, anti-nestin antibody revealed strong immunoreactivity in vascular cleft of the S-shaped body and vascular tuft of capillary loop-stage glomerulus. The nestin-positive structures also were labeled by endothelial cell markers FLK1 and CD31 in immature glomeruli. Nestin was not detected in epithelial cells of immature glomeruli. In contrast, in mature glomerular, nestin immunoreactivity was observed only outside laminin-positive glomerular basement membrane, and co-localized with nephrin, consistent with podocyte nestin expression. In adult kidney, podocytes were the only cells that exhibited persistent nestin expression. Nestin was not detected in ureteric bud and its derivatives throughout renal development. Cell lineage studies, using a nestin promoter-driven Cre mouse and a ROSA26 reporter mouse, showed a strong beta-galactosidase activity in intermediate mesoderm in an embryonic day 10 embryo and all of the structures except those that were derived from ureteric bud in embryonic kidney through adult kidney. These studies show that nestin is expressed in progenitors of glomerular endothelial cells and renal progenitors that are derived from metanephric mesenchyme. In the adult kidney, nestin expression is restricted to differentiated podocytes, suggesting that nestin could play an important role in maintaining the structural integrity of the podocytes.     

Hyperglycemia and development of glomerular pathology: diabetes compared with galactosemia

Dogs were randomly assigned to experimental galactosemia or diabetes, or to a normal untreated group, and diabetic animals were then randomly assigned to either poor or good glycemic control. At five years duration, kidneys from the animals were compared by quantitative stereology. Glomerulopathy appeared in the poor control diabetes group, and the thickness of glomerular capillary basement membrane, the glomerular tuft volume, and the fraction of glomerulus occupied by mesangium were each significantly greater than normal. The capillary filtering surface area per glomerulus was supranormal also, but nonetheless was subnormal relative to glomerular volume. The development of glomerulopathy was significantly inhibited in dogs assigned to good glycemic control. In galactosemic animals, the basement membrane thickness was greater than normal, but the glomerular volume, fractional and absolute volumes of mesangium, and capillary filtering surface area remained normal. The polyol concentration in renal cortex seemed elevated by galactosemia no less than by diabetes, and was highest in galactosemia. The galactosemic animals are known to have developed a retinopathy morphologically comparable to that of diabetic patients and diabetic dogs. Thus, sequelae of hyperglycemia sufficient to produce glomerular basement membrane thickening and retinopathy proved not necessarily sufficient to produce the mesangial expansion and glomerular hypertrophy typical of diabetes.