Composition of renal basement membranes isolated under various conditions

A Self T Cell Epitope Induces Autoantibody Response: Mechanism for Production of Antibodies to Diverse Glomerular Basement Membrane Antigens

The anti-glomerular basement membrane (GBM) Ab has been regarded as a prototypical example of pathogenic autoantibodies. However, the mechanism for elicitation of this Ab remains unknown. In the present paper, we report that the Ab to diverse GBM Ags was induced by a single nephritogenic T cell epitope in a rat model. The T cell epitope pCol(28-40) of noncollagen domain 1 of collagen type IV alpha3 chain not only uniformly induced severe glomerulonephritis but also elicited anti-GBM Ab in 76% of the immunized rats after prominent glomerular injury. Furthermore, we demonstrated that the anti-GBM Ab was not related to the peptidic B cell epitope nested in pCol(28-40); that is, 1) elimination of the B cell epitope, either by substitution of the critical residues of the B cell epitope or by truncation, failed to abrogate anti-GBM Ab production, and 2) the anti-GBM Ab, eluted from the diseased kidneys, reacted only with native GBM, but not with pCol(28-40). Confocal microscopy and immunoprecipitation further demonstrated that the eluted anti-GBM Ab recognized conformational B cell epitope(s) of multiple native GBM proteins. We conclude that autoantibody response to diverse native GBM Ags was induced by a single nephritogenic T cell epitope. Thus, anti-GBM Ab may actually be a consequence of T cell-mediated glomerulonephritis.

Age-related changes in the plasma membrane proteoglycans of rat kidney glomerular cells

In a previous in vivo study, we showed that the glomerular cells of rat kidney synthesize both peripheral and integral plasma membrane proteoglycans. The present work focuses on the age-related changes in these cell membrane proteoglycans. The peripheral proteoglycans in "adult control" rats aged 3 months were found to be heparan sulfate, dermatan sulfate, and chondroitin sulfate, with heparan sulfate being the main glycosaminoglycan. The integral membrane proteoglycans contained mainly dermatan sulfate plus less amounts of heparan sulfate. The relative proportions of the glycosaminoglycans in the integral membrane proteoglycans changed between 1 and 3 months. In addition, the degree of sulfation increased in both families of proteoglycans, and this was associated with an increase in glycosaminoglycan synthesis in the peripheral proteoglycans. The nature and relative proportions of the glycosaminoglycans forming the proteoglycans, did not change with age, after 10 months, and neither did the amount of glycosaminoglycans. But, the degree of sulfation of both peripheral and integral membrane proteoglycans decreased. De novo synthesized proteoglycans from 24-month-old rats had a higher overall charge than did those at other ages, owing to the presence of sulfate and carboxylic groups. We conclude that, as for glomerular basement membrane proteoglycans, biochemical alterations affect the glomerular cell membrane proteoglycans with aging.

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.