Ralph J. Butkowski

Alport familial nephritis. Absence of 28 kilodalton non-collagenous monomers of type IV collagen in glomerular basement membrane.

Alport-type familial nephritis (FN), a genetic disorder, results in progressive renal insufficiency and sensorineural hearing loss. Immunochemical and biochemical analyses of the non-collagenous (NC1) domain of type IV collagen isolated from the glomerular basement membranes (GBM) of three males with this disease demonstrate absence of the normally occurring 28-kilodalton (kD) NC1 monomers, but persistence of the 26- and 24-kD monomeric subunits derived from alpha 1 and 2 (both type IV) collagen chains, respectively.

Characterization of monoclonal antibodies to the globular domain of collagen IV

Monoclonal antibodies were produced against NC1, the globular noncollagenous domain of collagen IV, isolated from bovine glomerular basement membrane. Cells from eight positive wells were cloned and the resulting monoclonal antibodies were studied in detail by immunofluorescence on human kidney sections, by Western blot and by ELISA against denatured subunits from NC1 hexamers and against native NC1 hexamers from different tissues. The monoclonal antibodies could be divided into two groups. Firstly, those monoclonal antibodies that, in ELISA and Western blot, reacted with peptides related to the alpha 1 chain of collagen IV and stained all basement membranes in the kidney. Secondly, a monoclonal antibody that, in ELISA and Western blot, reacted with peptides related to the Goodpasture antigen, the alpha 3 chain of collagen IV. When this antibody was applied to human kidney sections it stained the glomerular basement membrane very intensively. Bowmans capsule and some tubular basement membrane were also stained, although to a lesser extent. This staining pattern is the same as that observed with sera from patients with Goodpastures syndrome. An attempt was made to separate different subtypes of the NC1 hexamer. A monoclonal antibody from the first group was used to make an affinity chromatography column. Glomerular basement membrane digested with collagenase was separated on this column and the collected fractions were analyzed by ELISA and SDS-PAGE. The result from this study support the idea that glomerular basement membrane is composed of at least two different subtypes of type IV collagen.

Alport syndrome, basement membranes and collagen

Alport syndrome, an inherited disorder of the kidney, eye and ear, has fascinated nephrologists, pathologists, and geneticists for nearly a century. With the recent application of molecular biochemical and genetic techniques, this mysterious disease has begun to yield some of its secrets. Alport syndrome can now be viewed as a generalized disorder of basement membranes that appears to result from mutations in an X-chromosome-encoded basement membrane collagen chain. This chain, along with two other novel collagen chains, is absent from Alport basement membranes, in contrast to the classical chains of collagen IV. Phenotypic heterogeneity in Alport syndrome probably arises from allelic mutations at a single genetic locus. The phenomenon of post-transplant anti-glomerular basement membrane nephritis may be a manifestation of specific mutations at the Alport locus that prevent synthesis of the genes protein product and the establishment of immunological tolerance.

Role of antibodies to tubulointerstitial nephritis antigen in human anti-tubular basement membrane nephritis associated with membranous nephropathy

We report three patients, from two unrelated families, with anti-tubular basement membrane (TBM) antibody nephritis associated with membranous nephropathy. This rare disorder is characterized by nephrotic syndrome, tubular dysfunction, and progression to renal failure. Direct immunofluorescent studies in these patients revealed linear IgG deposition along the proximal TBM, while circulating antibodies reacting with proximal TBM but not with glomerular basement membrane were identified by indirect immunofluorescence. Sera from all three patients reacted by enzyme-linked immunosorbent assay and Western immunoblotting with purified 58-kd tubulointerstitial nephritis (TIN) antigen isolated from TBM. Additional reactivity with a 175-kd component, which may be a higher-molecular-weight form of TIN antigen, was observed by immunoblotting. Since recurrent Fanconi syndrome was seen after transplantation in one patient, anti-TBM antibodies were removed by plasmapheresis prior to kidney transplantation in the other two patients. Neither patient has clinical evidence of recurrent anti-TBM nephritis in the allograft despite the posttransplantation reappearance of anti-TBM antibodies in the serum of one patient. Serologic and molecular HLA class I and class II polymorphism analysis has identified the presence of both HLA-B7 and -DRw8 antigens in two unrelated affected individuals (0.3% expected frequency in the white population). We conclude that sera from patients with anti-TBM nephritis associated with membranous nephropathy react with 58-kd TIN antigen previously implicated in the pathogenesis of primary anti-TBM nephritis. This rare autoimmune disorder may be HLA associated with B7 and/or DRw8, providing susceptibility to the disease. Further investigation is needed to understand the pathogenesis of recurrent anti-TBM nephritis in the renal allograft.

Differential expression of laminin isoforms in diabetic nephropathy and other renal diseases

Laminin a non-collagenous glycoprotein is a major component of the renal glomerular basement membrane and mesangium. Thus far eleven distinct chains have been described, permutations of which make up 15 laminin isoforms. Laminin molecules interact with cells and other matrix molecules during organ development and differentiation. We studied the distribution of laminin isoforms in patients with type 1 diabetic nephropathy, membranous nephropathy, membranoproliferative glomerulonephritis and IgA nephropathy/ Henoch–Schönlein purpura. Immunofluorescence microscopic studies with laminin-chain-specific antibodies to the α1, α2, α5, β1, β2 and γ1 chains detected α2, β1 and γ1 chain expression in the normal mesangium and α5, β2 and γ1 in normal glomerular basement membrane. Significantly, constituents of the glomerular basement membrane, α5, β2 and γ1 chains were overexpressed in kidneys with diabetic nephropathy. Initially the constituents of the mesangium increased commensurate with the degree of mesangial expansion and degree of diabetic nephropathy. Reduction in α2 chain intensity was observed with severe mesangial expansion and in the areas of nodular glomerulosclerosis. In addition, with late disease aberrant expression of α2 and β2 chains was observed in the mesangium. Glomerular basement membrane in renal disease overexpressed molecules normally present in that location. In summary, the alterations in basement membrane composition in various renal diseases seem to not only reflect the balance between synthesis and degradation of normal basement membrane constituents, but also their aberrant expression.

The Goodpasture Antigen: Common Epitopes in the Globular Domains of Collagen IV

To determine the nature of Goodpasture antibody-reactive epitopes on the globular domains of collagen IV [non collagenous (NC) domain], Goodpasture antigen was characterized by immunochemical and immunohistological techniques using affinity-purified (AP) Goodpasture autoantibodies. Affinity purification of Goodpasture autoantibodies toward alpha 1(IV), alpha 2(IV), and alpha 3(IV) NC domains was performed and revealed antigenic cross-reactivity with all alpha(IV) NC domain subunits, which was confirmed by inhibition ELISA. Since by immunofluorescent microscopy all 3 AP Goodpasture antibodies only stained the central portion (lamina densa) of bovine glomerular basement membrane, it appears that there are common epitopes reactive with Goodpasture autoantibodies present on alpha 1(IV) NC, alpha 2(IV) NC, and alpha 3(IV) NC domains.

Comparison of Non-Collagenous Type IV Collagen Subunits in Human Glomerular Basement Membrane, Alveolar Basement Membrane, and Placenta

This study examines the similarities and differences in the noncollagenous domain (NC1) of type IV collagen from human glomerular basement membrane (hGBM), alveolar basement membrane (hABM), and placenta (hPBM). Following collagenase digestion, NC1 domain was isolated on Bio-Gel A-0.5m or by cation exchange chromatography on S-Sepharose. NC1 from each source was characterized by SDS PAGE, and two dimension NEPHGE/SDS PAGE. Immunoblotting and ELISA inhibition was performed using antibody probes specific for M28 , M28+, M26 and M24 monomer subunits of human NC1. It was observed that all NC1 subunits were present in hGBM and hABM derived material, however M28 and M28+ monomers were absent in hPBM NC1. These findings indicate that while alpha 1(IV) and alpha 2(IV) collagen chains are present in hGBM, hABM and hPBM, alpha 3(IV) and alpha 4(IV) collagen chains are only found in hGBM and hABM but are absent in hPBM. It can now be appreciated that heterogeneity of alpha (IV) chain composition exists in basement membranes from various organs.

Renal cell carcinomas and pancreatic adenocarcinomas produce nidogen in vitro and in vivo

The production of nidogen by four renal cell carcinoma (RCC) and three pancreatic adenocarcinoma (PAc) cell lines has been studied in cell culture and in xenografted tumours in nude mice. In RCC cells, immunoreactivity for nidogen was seen only after exposure to monensin to induce cytoplasmic accumulation of secretory proteins. In PAc cells, immunoreaction was also detectable in control cells. Immunoblotting of control and monensin‐exposed cells and immunoprecipitation of culture media of radioactively labelled cells demonstrated the production of nidogen polypeptide of Mr ca. 150000 by six of the seven cell lines. Basement membranes (BMs) and stroma of the xenografted tumours derived from these six cell lines demonstrated immunoreactivity for both human and mouse nidogen, as revealed with species‐specific antibodies. The ability of the cells to produce nidogen in vitro and deposit in vivo was positively correlated with high histological grade of the xenografted tumours, although the small number of cell lines studied calls for further studies to confirm this. The distribution of nidogen in human RCC and PAc specimens was also studied by immunohistochemistry. There was strong immunoreactivity for nidogen in tumour stroma, BM of carcinoma cell nests, and endothelial basal lamina, but no conclusions could be drawn regarding histological grade and immunostaining patterns, because stromal production could not be ruled out. The results show that nidogen is produced by human carcinoma cells both in vitro and in vivo. Copyright

A METHOD FOR PREPARATION OF RENAL TUBULAR BASEMENT MEMBRANE

A method is presented for the preparation of tubular basement membrane from renal cortex. The procedure utilizes a Polytron tissue disrupter, differential sieving, and for some species, sucrose density centrifugation. The procedure is especially useful for obtaining highly purified rabbit and bovine tubular basement membranes. Human tubular and glomerular basement membranes can be prepared with some cross contamination. The method offers the capability of rapidly generating large quantities of the basement membranes that retain the Goodpasture antigen and a TBM antigen associated with anti-TBM nephritis.

Tubulointerstitial nephritis antigen (TIN-ag) is expressed in distinct segments of the developing human nephron

Tubulointerstitial nephritis antigen (TIN-ag) is a 58 kDa glycoprotein restricted within the kidney to basement membranes underlying the epithelium of Bowmans capsule and proximal and distal tubules. Autoantibody formation against this component has been described in association with primary immune-mediated tubulointerstital nephritis, membranous nephropathy and anti-glomerular basement membrane nephritis. In the present report, the ontogeny of this protein was studied in human fetal kidney tissue by immunohistochemical analysis of immature and developing nephrons using a panel of monoclonal and polyclonal antibodies. TIN-ag is first detected in basement membranes underlying the epithelium of Bowmans capsule of early capillary loop stage glomeruli and the primitive proximal tubule. No detectable expression is observed in the basement membranes of the branching ureteric bud, nephrogenic vesicle, or comma shape and s-shape stages of nephrogenic development. Increased staining of the proximal tubular basement membrane is associated with outgrowth of the primitive tubule from the urinary pole of the developing glomerulus. In more mature fetal tubules, TIN-ag expression closely resembles that of previously reported observations in mature tissue where it is present in high amounts in the basement membranes of proximal tubules, and to a lesser extent in Bowmans capsule and distal tubules. Our results suggest that TIN-ag expression is developmentally regulated in a precise spatial and temporal pattern throughout nephrogenesis.