Tissue factor pathway inhibitor expression in human crescentic glomerulonephritis

BACKGROUND: Tissue factor (TF) pathway inhibitor (TFPI), the major endogenous inhibitor of extrinsic coagulation pathway activation, protects renal function in experimental crescentic glomerulonephritis (GN). Its glomerular expression and relationship to TF expression and fibrin deposition in human crescentic GN have not been reported. METHODS: Glomerular TFPI, TF, and fibrin-related antigen (FRA) expression were correlated in renal biopsies from 11 patients with crescentic GN. Biopsies from 11 patients with thin basement membrane disease and two normal kidneys were used as controls. RESULTS: TFPI was undetectable in control glomeruli but was detectable in interstitial microvessels. In crescentic biopsies, TFPI was detected in cellular crescents and was more prominent in fibrous/fibrocellular crescents, indicating a correlation with the chronicity of crescentic lesions. TFPI appeared to be associated with macrophages but not endothelial or epithelial cells. TFPI was generally undetectable in regions of the glomerular tuft with minimal damage. In contrast, TF and FRA were strongly expressed in regions of minimal injury, as well as in more advanced proliferative and necrotizing lesions. Despite prominent TF expression, FRA was less prominent in fibrous/fibrocellular crescents in which TFPI expression was maximal. CONCLUSIONS: These data suggest that TFPI is strongly expressed in the later stages of crescent formation and is inversely correlated with the presence of FRA in human crescentic GN. This late induction of TFPI may inhibit TF activity and favor reduced fibrin deposition in the chronic stages of crescent formation.     

Role of integrin-linked kinase in epithelial-mesenchymal transition in crescent formation of experimental glomerulonephritis.

BACKGROUND: Glomerular parietal epithelial-mesenchymal transition (EMT) is a key event in crescent formation of glomerulonephritis (GN). Integrin-linked kinase (ILK) is an integrin cytoplasmic-binding protein that has been implicated in the regulation of cell adhesion, extracellular matrix organization and EMT. Transforming growth factor-beta (TGF-beta) is involved in the induction and progression of EMT in several tissues. METHODS: To investigate whether ILK is involved in the crescent formation in GN, we studied the expression of ILK protein and activity in crescentic GN induced in Wistar Kyoto (WKY) rats. In addition, we investigated whether transforming growth factor-beta1 (TGF-beta1) could induce glomerular EMT and ILK by using cultured parietal epithelial cell (PEC). RESULTS: The expression of ILK was strongly induced in cellular crescents at day 7 and followed by a decrease in fibrocellular crescents at day 28. ILK-expressing cells in cellular crescents were double-positive for protein gene product 9.5 (PEC marker), alpha-smooth muscle actin (alpha-SMA, myofibroblasts marker) and TGF-beta1, indicating a possible contribution of ILK and TGF-beta1 to EMT in crescent formation in GN. Consistent with the finding of histological ILK expression in crescents, western blot and kinase activity assay showed an increase in both ILK protein and activity, peaking at day 7 of GN (3.7- and 3.5-fold of control, respectively). The expression of ILK increased to 3.1-fold of control when EMT was induced in cultured PEC by TGF-beta1. CONCLUSION: The present results provide the first evidence that expression and activity of ILK are increased in cellular crescents of experimental GN. Enhanced expression and activity of ILK, possibly by TGF-beta1, is associated with the induction of EMT by PEC and thereby, may participate in the formation of cellular crescents in GN.     

Glomerular expression of C-C chemokines in different types of human crescentic glomerulonephritis.

BACKGROUND: Crescentic glomerulonephritis (CGN) presents a rapidly progressive glomerulonephritis clinically, in which macrophages play a crucial role in the pathogenesis. However, the precise molecular mechanism of macrophage recruitment and activation has not been fully elucidated. C-C chemokines, monocyte chemoattractant protein-1 (MCP-1) and macrophage inflammatory protein-1alpha and beta (MIP-1alpha and MIP-1beta), are major chemoattractants for macrophages. We attempted to study the expression of C-C chemokines and their correlation with CD68-positive macrophages in crescentic glomeruli to investigate further their possible roles in crescent formation and progression to fibrosis in different types of human CGN. METHODS: The expression of MCP-1, MIP-1alpha, MIP-1beta and CD68 was detected in glomeruli with different forms of crescents (cellular, fibrocellular and fibrous crescents) by immunohistochemistry in serial sections of renal biopsies taken from 32 patients with biopsy-proven CGN including eight patients with anti-glomerular basement membrane (GBM) disease (type I CGN), 12 patients with immune complex-mediated CGN (type II CGN) and another 12 patients with pauci-immune CGN (type III CGN) enrolled in this study. Eight normal human kidneys were obtained from cadaveric renal transplant donors whose kidneys were technically unsuitable for transplantation, serving as controls. RESULTS: MCP-1, MIP-1alpha, MIP-1beta and CD68 were undetectable in glomeruli of normal kidney. In crescentic biopsies, MCP-1, MIP-1alpha, MIP-1beta and CD68 were detected in fibrocellular crescents and were even more prominent in cellular crescents, but were undetectable in fibrous crescents. Using consecutive sections for staining, it was demonstrated that a high proportion of infiltrating CD68-positive macrophages, mainly localized to the area of the expression of chemokines, were MCP-1, MIP-1alpha and MIP-1beta positive in crescents. Chemokines were expressed mainly by CD68-positive macrophages and parietal epithelial cells in crescents. The number of MCP-1- and MIP-1alpha-positive cells in glomeruli with cellular crescents was positively correlated with the number of CD68-positive cells (r = 0.568 and 0.749, respectively, both P < 0.01). The number of MCP-1- and MIP-1alpha-positive cells and the incidence of Bowman's capsule rupture in glomeruli of patients with type I CGN were higher than those of type II and type III CGN. CONCLUSIONS: These observations suggest that the expressed C-C chemokines, MCP-1, MIP-1alpha and MIP-1beta, may mediate the inflammatory process of crescent formation and progression to fibrosis. The strong correlation of MCP-1 and MIP-1alpha with infiltrating macrophages within glomeruli with cellular crescents suggested that these chemokines might be of particular importance for macrophage recruitment to this site. MCP-1 and MIP-1alpha were correlated to type I CGN with its more severe inflammatory course and worse prognosis. The variance of glomerular expression of C-C chemokines may contribute to the difference in histopathological features and prognosis in these three types of CGN.     

Glomerular epithelial-myofibroblast transdifferentiation in the evolution of glomerular crescent formation.

BACKGROUND:Glomerular cellular crescents consist of epithelial cells and macrophages, which can undergo an irreversible process of fibrous organization. However, the origin of the fibroblast-type cells that mediate this fibrous organization is unclear. METHODS: This study examined glomerular epithelial- myofibroblast transdifferentiation (GEMT) in the formation and evolution of glomerular crescents in two distinct rat models of glomerulonephritis: 5/6 nephrectomy and antiglomerular basement membrane (GBM) disease. RESULTS: Early in the course of both disease models, and prior to crescent formation, immunohistochemistry staining and in-situ hybridization demonstrated de novo expression of alpha-smooth-muscle actin (alpha-SMA), a marker of smooth muscle cells and myofibroblasts, by glomerular parietal epithelial cells (GPEC). The expression of alpha-SMA by GPEC was accompanied by a loss of E-cadherin staining, a marker of epithelial cells. At this early stage of GEMT, ultrastructural studies identified the presence of characteristic actin microfilaments and dense bodies within GPEC which retained a normal epithelial morphology with apical-basal polarity and microvilli. A late stage of transdifferentiation was seen in fibrocellular crescents. In this case, GPEC attached to intact segments of the capsular basement membrane contained large bundles of actin microfilaments throughout the cell, and this was accompanied by a loss of polarity, microvilli, and tight junctions. There was a significant correlation between the presence of alpha-SMA(+) GPEC and glomerular crescent formation. Cellular crescents contained small numbers of alpha-SMA(+) myofibroblasts. These cells become the dominant population in fibrocellular crescents, which was associated with marked local proliferation. Relatively few alpha-SMA(+) myofibroblasts remained in fibrotic/organizing crescents. Most cells within cellular and fibrocellular crescents expressed transforming growth factor-beta (TGF-beta) and basic fibroblast growth factor (FGF-2), suggesting that these growth factors may regulate this GEMT process during the evolution of glomerular crescents. CONCLUSIONS: This study provides the first phenotypic and morphological evidence that glomerular epithelial-myofibroblast transdifferentiation participates in the formation and evolution of glomerular crescents.     

Podocyte involvement in human immune crescentic glomerulonephritis

BACKGROUND: The role of podocytes in human crescentic glomerulonephritis (GN) has been underestimated. This may be due to the confounding fact that "dysregulated" podocytes are able to proliferate, lose their markers, and acquire new epitopes. Moreover, in experimental anti-glomerular basement membrane (GBM) crescentic GN, podocytes participate in the crescent formation. The aim of this study was to investigate the involvement of podocytes in human immune crescentic GN. METHODS: Renal biopsies from 12 patients with anti-GBM disease and 14 with class IV lupus GN were studied by immunohistochemistry for the following markers: (1) synaptopodin, GLEPP1, podocalyxin, podocin, alpha-actinin-4, and vimentin for podocyte identification; (2) PCNA, Ki-67, and p57 for cell cycle assessment; (3) cytokeratins for identifying epithelial cells but not normal podocytes; (4) CD68 for tagging a macrophagic epitope; (5) alpha-smooth-muscle actin (alpha-SMA), a phenotypic marker of myofibroblasts. RESULTS: "True" (capsular) crescents lining Bowman's capsule and (tuft) "pseudocrescents" covering the glomerular tuft with a persistent patent urinary space were present in the 2 types of crescentic GN in similar percentages. Several features indicated that podocytes were involved in the formation of the both crescent types. Identifiable podocytes expressed proliferation markers. Podocyte cytoplasmic expansions and racket-like podocytes bridged between the tuft and Bowman's capsule. True and pseudocrescents contained labeled podocytes. In addition, podocytes located outside of the crescents had often lost their markers (dedifferentiation) and acquired new epitopes (cytokeratins and CD68). CONCLUSION: In human immune crescentic GN, podocytes undergo proliferation and dysregulation that are indicative of a podocytopathy. Podocytes contribute to crescent formation.     

T cells in crescentic glomerulonephritis

Crescent formation in glomerulonephritis (GN) is a manifestation of severe glomerular injury that usually results in a poor clinical outcome. In humans, crescentic GN is frequently associated with evidence of either systemic or organ-specific autoimmunity. T cells play a major role in initiation of adaptive immune responses that lead to crescentic injury. In experimental models of crescentic GN, Th1 predominant immune responses have been shown to promote crescent formation. Perturbation of regulatory T cell function may contribute to development of autoimmune crescentic GN. The presence of T cells and macrophages in crescentic glomeruli, frequently in the absence of humoral mediators of immunity, suggest a dominant effector role for T cells in crescentic GN. The association of cellular immune mediators with local fibrin deposition implicates cell-mediated "delayed-type hypersensitivity-like" mechanisms in crescent formation. Intrinsic renal cells also contribute to T cell-driven effector mechanisms in crescentic GN, via expression of MHC II and co-stimulatory molecules and by production of chemokines and cytokines that amplify leukocyte recruitment and injury.     

Crescentic glomerulonephritis in children: a review of 43 cases.

Forty-three children with crescentic glomerulonephritis (GN), having large crescents in more than 50% of the glomeruli, were observed during a period of 22 years. There were 17 boys and 26 girls between the ages of 3.5 and 14 years (mean 8.7 +/- 2.6). Thirty-one patients (72%) presented with acute nephritic features and increasing renal insufficiency (rapidly progressive GN) whereas 12 had an insidious onset with nephrotic syndrome, or rarely with nonspecific symptoms. Eleven patients had evidence of poststreptococcal GN and 6 an underlying systemic disorder. Renal biopsy showed large crescents in greater than 80% of the glomeruli in 38 cases (100% in 28) which were predominantly fibrocellular or fibrous in 80% of the patients. Nineteen patients (44%) were treated with prednisolone, cyclophosphamide and dipyridamole; in addition, 8 were also given anticoagulants. Six patients received pulse doses of corticosteroids. In 23 patients, there was inexorable progression of renal failure, 14 showed partial improvement but subsequently had varying degrees of renal insufficiency and in 6, there was recovery of renal function with normal levels of serum creatinine. Of the latter, 4 had received immunosuppressive anticoagulant therapy and 2 only supportive care. Of 11 patients with poststreptococcal crescentic GN, 7 progressed to end-stage renal disease and 2 developed chronic renal insufficiency. Our findings confirm the poor outcome of crescentic GN in children, irrespective of the underlying etiology. In a small proportion of cases, the disorder may have an insidious onset and a slowly progressive course, but an equally grave prognosis.     

Podocytes contribute to the formation of glomerular crescents

The cellular composition of crescents in glomerular disease is controversial. The role of podocytes in crescent formation has been especially difficult to study because podocytes typically lose their characteristic terminally differentiated phenotype under disease conditions, making them difficult to identify. We reasoned that the intermediate filament protein nestin, a marker of progenitor cells that has recently been identified in podocytes, may allow the investigation of podocyte involvement in glomerular crescents. In a series of 35 biopsies with crescentic glomerular disease, all showed nestin-positive cells in the crescents, ranging in number from occasional to approximately 50% of crescent cells. Other podocyte markers, such as podocin and WT1, failed to identify cells in crescents, and no contribution by endothelial or myogenic cells was noted. CD68-positive cells were observed in 80% of cases but were never as numerous as the nestin-positive cells. Nestin and CD68 were not coexpressed by the same cells, providing no evidence of trans-differentiation of podocytes into a macrophage phenotype. Keratin-positive cells were found in crescents in 51% of cases, but only as occasional cells. Up to one third of crescent cells were cycling in 48% of biopsies, and double immunostaining identified these cells as a mixture of nestin-positive cells and "null" cells (negative for nestin, CD68, and keratin). In addition to our observations in human disease, we also identified nestin-positive proliferating podocytes in the crescents of 2 mouse models of crescentic glomerulonephritis. We conclude that podocytes play a role in the formation of glomerular crescents.     

Urinary FSP1 is a biomarker of crescentic GN

Fibroblast-specific protein 1 (FSP1)-expressing cells accumulate in damaged kidneys, but whether urinary FSP1 could serve as a biomarker of active renal injury is unknown. We measured urinary FSP1 in 147 patients with various types of glomerular disease using ELISA. Patients with crescentic GN, with or without antinuclear cytoplasmic antibody-associated GN, exhibited elevated levels of urinary FSP1. This assay had a sensitivity of 91.7% and a specificity of 90.2% for crescentic GN in this sample of patients. Moreover, we found that urinary FSP1 became undetectable after successful treatment, suggesting the possible use of FSP1 levels to monitor disease activity over time. Urinary FSP1 levels correlated positively with the number of FSP1-positive glomerular cells, predominantly podocytes and cellular crescents, the likely source of urinary FSP1. Even in patients without crescent formation, patients with high levels of urinary FSP1 had large numbers of FSP1-positive podocytes. Taken together, these data suggest the potential use of urinary FSP1 to screen for active and ongoing glomerular damage, such as the formation of cellular crescents.     

Localization and roles of CD44, hyaluronic acid and osteopontin in IgA nephropathy.

An important function of CD44 is to act as a cellular receptor for hyaluronic acid and osteopontin. Cell-matrix interactions mediated by the CD44/hyaluronic acid receptor-ligand pair are involved in the regulation of leukocyte migration and activation. Osteopontin is a molecule associated with cell adhesion and migration and functions through binding to CD44. This study examined whether CD44, hyaluronic acid and osteopontin participate in the progression of IgA nephropathy. CD44 was expressed in mesangial cells, crescents, tubular cells and interstitial infiltrating cells in areas of tubulointerstitial injury. Hyaluronic acid was deposited in the capillary tuft of adhesion, crescents and the periglomerular area, and around damaged tubules. Osteopontin was expressed in tubular cells and interstitial infiltrating cells in areas of tubulointerstitial injury. The glomerular and interstitial deposition of hyaluronic acid correlated with the glomerular and interstitial expression of CD44. The interstitial expression of CD44 correlated with the interstitial expression of osteopontin. The expression of both CD44 and osteopontin in the interstitium correlated with the extent of tubulointerstitial damage. The expression of CD44 in the interstitium correlated with the severity of chronic glomerular lesions. The glomerular and interstitial CD44 and hyaluronic acid expression correlated with proteinuria, and interstitial CD44 and hyaluronic acid expression correlated with creatinine clearance rate. In summary, this study suggests that CD44 participates in the progression of IgA nephropathy by binding hyaluronic acid and osteopontin.     

Expression of gremlin, a bone morphogenetic protein antagonist, in glomerular crescents of pauci-immune glomerulonephritis.

BACKGROUND: Recent evidence in vitro and in vivo suggests that gremlin, a bone morphogenetic protein antagonist, is participating in tubular epithelial mesenchymal transition (EMT) in diabetic nephropathy as a downstream mediator of TGF-beta. Since EMT also occurs in parietal epithelial glomerular cells (PECs) leading to crescent formation, we hypothesized that gremlin could participate in this process. With this aim we studied its expression in 30 renal biopsies of patients with pauci-immune crescentic nephritis. METHODS: Gremlin was detected by in situ hybridization (ISH) and immunohistochemistry (IMH) and TGF-beta by ISH and Smads by southwestern histochemistry (SWH). Phosphorylated Smad2, CTGF, BMP-7, PCNA, alpha-SMA, synaptopodin, CD-68, and phenotypic markers of PECs (cytokeratin, E-cadherin), were detected by IMH. In cultured human monocytes, gremlin and CTGF induction by TGF-beta was studied by western blot. RESULTS: We observed strong expression of gremlin mRNA and protein in cellular and fibrocellular crescents corresponding to proliferating PECs and monocytes, in co-localization with TGF-beta. A marked over-expression of gremlin was also observed in tubular and infiltrating interstitial cells, correlating with tubulointerstitial fibrosis (r=0.59; P<0.01). A nuclear Smad activation in the same tubular cells, that are expressing TGF-beta and gremlin, was detected. In human cultured monocytes, TGF-beta induced gremlin production while CTGF expression was not detected. CONCLUSION: We postulate that gremlin may play a role in the fibrous process in crescentic nephritis, both in glomerular crescentic and tubular epithelial cells. The co-localization of gremlin and TGF-beta expression found in glomeruli and tubular cells suggest that gremlin may be important in mediating some of the pathological effects of TGF-beta.     

Up-regulation of extracellular matrix proteoglycans and collagen type I in human crescentic glomerulonephritis

BACKGROUND: The pathogenesis of crescentic glomerulonephritis (CGN) involves cellular migration and proliferation in the urinary space, frequently followed by fibrous organization. Extracellular matrix proteoglycans (PGs) may regulate these events via effects on cellular migration, interactions with growth factors, including transforming growth factor-beta (TGF-beta), and control of collagen fibrillogenesis. The expression of PG in human CGN is unknown. METHODS: Renal tissues from 18 patients with CGN were examined immunohistochemically for versican, decorin, biglycan and collagen type I, and were compared with morphologically normal tissues from six tumor nephrectomies. Synthesis of decorin, biglycan, and procollagen type I mRNAs was evaluated by in situ hybridization. RESULTS: Versican was strongly expressed in cellular crescents and periglomerular areas, whereas decorin and biglycan accumulated in collagen type I-enriched regions, including fibrocellular and fibrous crescents, and interstitial fibrosis. PG and collagen type I accumulation colocalized with myofibroblasts in crescents, periglomerular areas, and interstitium. CONCLUSIONS: The temporal and spatial patterns of expression demonstrated in this study provide evidence to support pathogenic roles for PG in the evolution of CGN. Based on known biological properties of this molecule, versican may facilitate migration of cells in developing crescents. Decorin and biglycan may contribute to progression of CGN, perhaps via interactions with collagen type I in the remodeled extracellular matrix.     

Expression of basic fibroblast growth factor and its receptor in the progression of rat crescentic glomerulonephritis

Summary: The aim of this study was to examine the relationship of basic fibroblast growth factor (FGF-2) and its receptor (FGF-R) to tubular proliferation, interstitial fibrosis, glomerular cell proliferation and crescent formation in the development of anti glomerular basement membrane (GBM) glomerulonephrids in the rat. Using new microwave-based histochemistry techniques, weak constitutive expression of mRNA and protein for FGF-2 and FGF-R was evident in tubules and glomeruli of normal rat kidney. Double and triple staining with the proliferating cell nuclear antigen (PCNA) demonstrated that in disease there was focal up-regulation of FGF-2 and FGF-R mRNA and protein expression within proliferating tubules and fibroblast-like cells in areas of interstitial fibrosis. In contrast, tubules in non-inflamed areas of kidney showed no change in FGF-2 and FGF-R expression or cellular proliferation. In addition, many FGF-2⁺PCNA⁺ and FGF-R⁺PCNA⁺ cells, probably mesangial cells and podocytes, were evident within glomerular segmental proliferative lesions. of particular interest was the observation that many epithelial cells within cellular crescents, inculding proliferating (PCNA⁺) epithelial cells, strongly expressed both FGF-2 and FGF-R. Furthermore, there was strong FGF-2 and FGF-R expression by proliferating fibroblast-like cells within fibrocellular crescents suggesting that FGF-2 is involved in the formation and fibrotic progression of glomerular crescents. In conclusion, this study provides evidence that increased expression of FGF-2 and its receptor may participate in the proliferative/fibrotic response in progressive crescentic glomerulonephritis.     

Glomerular basement membrane necrosis and crescent organization

In order to reveal structural damage to the glomerular basement membranes occurring in crescentic glomerulonephritis and the subsequent connective tissue organization of the crescent, 14 kidney biopsies were treated with detergents to remove cellular components and the tissue remaining examined by transmission (TEM) and scanning (SEM) electron microscopy. The fourteen biopsies were divided into two groups for analysis. Group I (7 cases) contained necrotizing lesions and cellular crescents. Acellular TEM (ATEM) revealed widespread lysis of mesangial matrix, while acellular SEM (ASEM) of five cases revealed three general patterns of GBM necrosis. Group II (7 cases) contained fibrocellular and fibrosis crescents. ATEM and ASEM revealed that collagen fibers initially form along fibrin fibrils and eventually result in formation of lacunar spaces occupied by cells of the crescent. Fibrous crescents were associated with prominent glomerular tuft distortion and entrapment of normal capillary loops. Continuity between interstitial space, matrix of crescent and mesangium were often observed. These observations suggest that lysis of mesangial matrix is extensive and precedes GBM lysis while the pattern of GBM damage fits best with local release of lytic factors. Furthermore, the architectural distortion and continuity which develops between normally segregated compartments (mesangial-interstitial) indicate that both the initial necrosis and the reparative response to injury, contribute substantially to overall nephron dysfunction.     

Osteopontin expression in human crescentic glomerulonephritis

Osteopontin expression in human crescentic glomerulonephritis. BACKGROUND: Osteopontin is a molecule with diverse biological functions, including cell adhesion, migration, and signaling. The expression of osteopontin has been demonstrated in a number of models of renal injury in association with accumulations of monocyte/macrophages, including recent reports of osteopontin expression in glomerular crescents in a rat model of anti-glomerular basement membrane glomerulonephritis. METHODS: Glomerular expression of osteopontin in biopsies of human crescentic glomerulonephritis (N = 25), IgA nephropathy with crescents (N = 2), and diffuse proliferative lupus glomerulonephropathy with crescents (N = 1) was studied by immunohistochemistry, in situ hybridization, and combined immunohistochemistry/in situ hybridization. Additionally, antibodies to cell-specific phenotypic markers were used to identify cellular components of the glomerular crescent, which express osteopontin protein and mRNA. RESULTS: All of the crescents present in the biopsies studied contained a significant number of cells that expressed osteopontin protein and mRNA, demonstrated by immunohistochemistry and in situ hybridization, respectively. Using replicate tissue sections and combined immunohistochemistry/in situ hybridization, we showed that the majority of the strongly osteopontin-positive cells are monocyte/macrophages. In addition to the very strong and cell-associated localization, a weaker and more diffuse pattern of osteopontin protein and mRNA expression could be seen in a number of crescents. None of the osteopontin mRNA-expressing cells could be identified as parietal epithelial cells, CD3-positive T cells, or alpha-smooth muscle actin-positive myofibroblasts. Interstitial monocyte/macrophages did not express osteopontin, except when located in a periglomerular inflammatory infiltrate. CONCLUSIONS: Macrophages present in the human glomerular crescent express osteopontin protein and mRNA at a high level. This expression supports a role for osteopontin in the formation and progression of the crescentic lesion via chemotactic and signaling properties of the molecule.     

Mechanisms and kinetics of Bowman's epithelial-myofibroblast transdifferentiation in the formation of glomerular crescents

BACKGROUND: We investigated the mechanisms and kinetics of Bowman's epithelial-myofibroblast transdifferentiation in the formation of glomerular crescents. METHODS: Crescentic glomerulonephritis was induced by i.v. injection of rabbit anti-rat glomerular basement membrane antiserum in WKY rats. RESULTS: Cellular crescents (83.5% of glomeruli) were first observed at day 7 after disease induction. Immunostaining of alpha-smooth muscle actin (alpha-SMA), as a marker for the myofibroblast phenotype, was found in some periglomerular regions as early as day 3, when it was also seen in parietal epithelial cells (PEC) of Bowman's capsule at day 5 and in crescent formation at day 7. Proliferation marker Ki67-positive PEC was found at day 3, and double Ki67- and alpha-SMA-positive PEC could be seen at day 5. The migratory figure of PEC with the expression of alpha-SMA was found by immunoelectron microscopy. At day 7, some crescent cells were stained positive for PEC marker, protein gene product 9.5, in association with alpha-SMA or Ki67. Expression of transforming growth factor (TGF)-beta receptor types I and II, as well as platelet-derived growth factor (PDGF) receptor beta and PDGF-B increased in PEC as early as day 3. At day 5 marked deposition of cellular and common fibronectin, but not other extracellular matrix components examined was found in Bowman's spaces where ED 1-positive macrophages infiltrated. CONCLUSIONS: PEC may be stimulated to proliferate and/or transdifferentiate into myofibroblast phenotype possibly by action of TGF-beta and PDGF and/or binding of fibronectin to PEC, then migrate and/or proliferate, participating in glomerular crescents.     

Glomerular epithelial-mesenchymal transdifferentiation in pauci-immune crescentic glomerulonephritis.

BACKGROUND: Among the cellular changes occurring in renal fibrosis, epithelial-mesenchymal cell transdifferentiation or transition (EMT) is a phenomenon characterized in epithelial cells by loss of epithelial markers and acquisition of mesenchymal phenotype and of fibrosing properties. METHODS: To test the hypothesis that EMT is involved in human pauci-immune crescentic glomerulonephritis (PICGN), we studied 17 renal biopsies from 11 PICGN patients for: (i) proliferating cell nuclear antigen (PCNA) and cell cycle inhibitors (cyclin-dependent kinase inhibitors) p27 and p57; (ii) cell lineage phenotype markers: podocalyxin, synaptopodin and GLEPP-1 for podocytes; CD68 for macrophagic epitope; CD3 for T lymphocytes; alpha-smooth muscle actin (alpha-SMA) for myofibroblasts; vimentin for mesenchymal cells; and cytokeratins (CKs) for parietal epithelial cells (PECs); (iii) glomerular fibrosis by labelling collagens I, III and IV, and heat-shock protein 47 (HSP47), a marker of collagen-synthesizing cells; and (iv) co-localization of alpha-SMA, CK and HSP47 using confocal laser microscopy. RESULTS: The crescent cells proliferated greatly. They did not express p27 and p57. Different cell lineage markers could be identified in crescents: the major component was made of 'dysregulated' PECs negative for CK, followed by PECs positive for CK, macrophagic cells and myofibroblasts. Furthermore, some cells co-expressed CK and alpha-SMA. This latter co-expression suggests a transitional phase in the dynamic phenomenon of EMT. Therefore, proliferative and dysregulated glomerular epithelial cells could be a possible cellular source of myofibroblasts via EMT. In addition, HSP47 labelled many crescent cells and frequently co-localized in CK-positive epithelial cells and in alpha-SMA-positive myofibroblasts, indicating that these cells were involved in glomerular accumulation of collagens. CONCLUSION: EMT is a transient cellular phenomenon present in glomeruli in human PICGN contributing to the formation of myofibroblasts from epithelial cells and to glomerular fibrosis.     

Plasma exchange combined with immunosuppressive treatment in a child with rapidly progressive IgA nephropathy

Although diffuse crescentic formation in immunoglobulin A (IgA) nephropathy, histologically characterized by extensive extracapillary proliferation, is assumed to have a poor prognosis, there has still been no established treatment because of the low prevalence of the condition, especially in pediatric patients. This paper reports on a 5-year-old boy with rapidly progressive IgA nephropathy requiring dialysis for 1 month. He had been treated with plasma exchange (PE) combined with immunosuppressive treatment, including steroids and mizoribine, because renal function deteriorated rapidly despite initial treatment with intravenous methylprednisolone pulse. The histological findings at that time revealed IgA nephropathy, with large circumferential cellular crescent formation in approximately 80% of the glomeruli. Three weeks after PE initiation, serum levels of creatinine and IgA-containing immune complexes returned to normal, and urinary protein excretion gradually decreased. The second renal biopsy taken 7 months later demonstrated mild IgA nephropathy with small fibrocellular crescents. This case report indicates that PE combined with immunosuppressive treatment may benefit children with rapidly progressive IgA nephropathy, even when extensive crescent formations are present.