The glomerular basement membrane

The kidney's glomerular filtration barrier consists of two cells-podocytes and endothelial cells-and the glomerular basement membrane (GBM), a specialized extracellular matrix that lies between them. Like all basement membranes, the GBM consists mainly of laminin, type IV collagen, nidogen, and heparan sulfate proteoglycan. However, the GBM is unusually thick and contains particular members of these general protein families, including laminin-521, collagen α3α4α5(IV), and agrin. Knockout studies in mice and genetic findings in humans show that the laminin and type IV collagen components are particularly important for GBM structure and function, as laminin or collagen IV gene mutations cause filtration defects and renal disease of varying severities, depending on the nature of the mutations. These studies suggest that the GBM plays a crucial role in establishing and maintaining the glomerular filtration barrier.     

Clogging of the glomerular basement membrane

The negative charges of the sulfated glycosaminoglycans (GAGs) of the glomerular basement membrane (GBM) were differentially neutralized by perfusin with high molarity buffers in order to determine whether or not these charges protect the GBM from being clogged by circulating plasma macromolecules. Progressive elimination of the negative charges resulted in clogging of the GBM by perfused native ferritin (NF) and bovine serum albumin as evidenced ultrastructurally by the increase in accumulation of NF in the GBM. In addition, the permeability of the GBM to 125I-insulin, a macromolecule which is normally freely permeable, and the glomerular filtration rate (as determined by [3H]inulin clearance) were markedly reduced after the GBM had been clogged with NF in the presence of high molarity buffer, thereby indicating that clogging severely reduces the ability of the GMB to act as a selective filter. These findings are consistent with the idea that the sulfated GAGs of the GBM serve as anticlogging agents.     

Studies of the permeation properties of glomerular basement membrane: cross-linking renders glomerular basement membrane permeable to protein

Cross-linking glomerular basement membrane (GBM) has been shown to render it more permeable to protein. Isolated pig GBM was cross-linked with dimethylmalonimidate which reacts selectively with lysine ?-NH₂ groups or with glutaraldehyde, a less selective cross-linking agent. Studies of the ultrafiltration properties of these materials in vitro using cytochrome c, myoglobin, bovine serum albumin and immunoglobulin showed that cross-linking had markedly increased solvent and protein fluxes as compared with native membranes particularly at higher pressures. Filtration studies with serum demonstrated that the cross-linked membranes were more permeable to serum proteins. Thickness measurements under pressure indicated that cross-linked membrane was less compressed than native membrane as pressure was increased. Pore theory did not provide a suitable model for analysis of the results, but analysis of the results using the fibre-matrix hypothesis indicated that cross-linking had the effect of bundling together the fibres (type IV collagen) in the GBM matrix. The effect of cross-linking on filtration could be explained by a combination of contraction of the membrane, fibre bundling and increased rigidity compared with native membrane. Cross-linking of GBM might lead to long-term damage of the glomerular capillary wall in nephritis, so promoting proteinuria.     

Studies of the permeation properties of glomerular basement membrane: cross-linking renders glomerular basement membrane permeable to protein.

Cross-linking glomerular basement membrane (GBM) has been shown to render it more permeable to protein. Isolated pig GBM was cross-linked with dimethylmalonimidate which reacts selectively with lysine epsilon-NH2 groups or with glutaraldehyde, a less selective cross-linking agent. Studies of the ultrafiltration properties of these materials in vitro using cytochrome c, myoglobin, bovine serum albumin and immunoglobulin showed that cross-linking had markedly increased solvent and protein fluxes as compared with native membranes particularly at higher pressures. Filtration studies with serum demonstrated that the cross-linked membranes were more permeable to serum proteins. Thickness measurements under pressure indicated that cross-linked membrane was less compressed than native membrane as pressure was increased. Pore theory did not provide a suitable model for analysis of the results, but analysis of the results using the fibre-matrix hypothesis indicated that cross-linking had the effect of bundling together the fibres (type IV collagen) in the GBM matrix. The effect of cross-linking on filtration could be explained by a combination of contraction of the membrane, fibre bundling and increased rigidity compared with native membrane. Cross-linking of GBM might lead to long-term damage of the glomerular capillary wall in nephritis, so promoting proteinuria.     

Metal-binding properties of the isolated glomerular basement membrane

The nature of binding of metal cations to the glomerular basement membrane has been investigated using isolated bovine glomerular basement membrane. Highest-affinity binding for a number of ions is attributable to the glycosaminoglycans (mostly heparan sulfate) of the membrane. Some ions, such as divalent Mn, Ca and Ni, have specific binding sites on these polymers, while for others the ion-polyelectrolyte interaction is of a non-specific nature. Both structural and binding data indicate a linear charge density of close to unity for the heparan sulfate of the glomerular basement membrane, which at the ionic composition of the plasma filtrate corresponds to a polymer surface potential of about -45 mV. Several independent observations are better explained by a model of counter-ion condensation about the glycosaminoglycans than by conventional double layer theories. These include the valence dependence of ion binding, the sharp ejection of divalent ions at a critical concentration of La3+, and the relative insensitivity of 63Ni2+ binding to NaCl concentration in the neighbourhood of physiological ionic strength. In its interactions with metal ions, the glomerular basement membrane behaves like a dilute solution of polyelectrolytes. This conclusion has important consequences for the extent of charge reduction of the filtration barrier of the kidney, bathed as it is in an electrolyte solution of mainly monovalent salts.     

Reducible cross-links in human glomerular basement membrane

Reducible cross-links in purified human glomerular basement membrane (GBM) were examined with an ion exchange chromatographic system that provided complete separation of cross-link standards and glucosylamines. After hydration in phosphate buffer, lyophilized GBM was reduced with tritiated borohydride. Chromatographic separation revealed two major radioactive peaks, identified as di-hydroxylysinonorleucine (di-OHLNL) and hydroxyaldolhistidine (HAH) by coelution with authentic di-OHLNL and HAH standards. Radioactive glucitol-lysine and glucitol-hydroxylysine were also identified on the basis of their co-elution with synthetic standards. The findings document the existence and establish the nature of the major reducible cross-links in adult human GBM.     

Ultrastructural development features of the human glomerular basement membrane

In the human embryo, the basement glomerular membrane appears early, at about ten weeks of age. The study of 36 human embryos aged 8-20 weeks revealed many arguments suggesting the epithelial origin of the basement membrane of the visceral capsula.     

Synthesis of the glomerular basement membrane in the rat kidney

To study the origin and the formation of the glomerular basement membrane, autoradiographic investigations with³H-proline and³H-leucine have been performed in ultrathin and semithin sections of the glomeruli of 42 male rats. The results of this study indicate that, of the three cell types of the glomerulus, the epithelial cells (=podocytes) synthesize the proline-rich scleroproteins of the glomerular basement membrane. Our autoradiographic studies have yielded no evidence for participation of the endothelial or mesangial cells in the formation of the basement membrane. The mesangial cells appear to be responsible for the synthesis of the mesangial matrix only.     

Phospholipid of the rat glomerular basement membrane in experimental nephrosis

Phospholipids were found to be a constant component of rat glomerular basement-membrane preparations. The concentration fell during preparation of basement membrane by sonication of whole glomeruli, but then remained constant despite continued sonication. The proportions of the individual phospholipids were different from those of whole renal tissue or of isolated glomeruli. The basement-membrane preparations had no (Na(+)+K(+))-activated adenosine triphosphatase activity, an enzyme that is bound to plasma membranes. The concentration of lipid P was decreased on exposure in vivo or in vitro to antiserum against basement membrane; 7 days after injection of antiserum there was a change in the phospholipid composition, with a relative increase in phosphatidylcholine and a decrease in sphingomyelin content. The metabolic turnover rate of the lipid P remaining in the membrane was normal, as determined by (32)P incorporation. The loss of phospholipid was associated with decreases in the relative concentrations of hydroxyproline, hydroxylysine and glycine, and relative increases in proline, lysine, serine, threonine and valine. Administration of aminonucleoside and daunomycin produced proteinuria but did not cause a decrease in lipid P. Anticollagen and anti-lymphocyte sera that attached to the basement membrane but failed to produce proteinuria, also failed to affect the phospholipid content.     

Differential solubility of subcomponents of rat glomerular basement membrane

Marked differences were found in the electrophoretic profiles and amino-acid compositions of components prepared from rat glomerular basement membrane (GBM) by a number of different solubilization procedures. Treatment with reducing agent resulted in a simplified electrophoretic pattern which was characterized by the presence of a major collagenous component with a mol.wt, of 150 000. In contrast, detergent solubilized mainly lower-mol.-wt, material which had a more polar amino-acid composition. When both reagents were used together the majority of the basement-membrane material was soJubilized within 2 h and components with mol.wts, of 170 000 and 135 000 were predominant i n the pro- region of the gel. Treatment for a further 16 h was required to solubilize higher-mol.-wt, material and to achieve maximum solubility of components in the pro- region with mol.wts, of 185 000 and 150 000. These methods provide a means of separating subcomponents of rat GBM while avoiding the problems of degradation inherent in enzymatic procedures.     

Increased glycosylation of glomerular basement membrane collagen in diabetes

Basement membrane was purified from glomeruli isolated from normal and streptozotocin-diabetic rats. After extraction of non-collagen protein with 8M urea, the extent of glycosylation in glomerular basement membrane collagen was determined with a specific colorimetric reaction that detects carbohydrate in ketoamine linkage with proteins. The level of glycosylation of glomerular basement membrane collagen purified from diabetic rats was significantly greater than that in non-diabetic animals. Increased basement membrane glycosylation may alter structure-function relationships of the capillary filtration barrier.     

Human glomerular basement membrane. Heterogeneity of antigenic determinants

Human glomerular basement membrane was solubilized by digestion with proteolytic enzymes and immunoreactive components were quantitated and characterized by using rabbit antibodies raised against the particulate membrane. A number of antigens were demonstrated but they did not separate on gel filtration. However, two antigenic components in a collagenase digest of the membrane could be separated and isolated by Sepharose 6B chromatography. Chemical characterization suggests that both fragments are noncollagenous glycopeptides (molecular weights approx. 1 000 000 and 60 000–200 000, respectively).