Successive steps leading to the development of glomerular ultrafiltration properties were explored in rat fetuses. The appearance of the lamina densa of the glomerular basement membrane (GBM) concurrently with a sharp rise in collagen biosynthesis suggest a prominent role for these events in restricting permeability to plasma proteins. Sieving functions of the glomerular barrier are shown to depend on macromolecular architecture of the GBM, negative-fixed charges of the laminae rarae representing only one factor in maintaining the structure required for selective permeability.
The role of collagen in ultrafiltration properties of the glomerular basement membrane (GBM) was tested after a single administration of bacterial collagenase, using native ferritin as a tracer which does not pass through the GBM under physiological conditions. Experiments were performed both in situ and with isolated kidneys. Increased permeability to ferritin occurs 6 hr following enzyme perfusion and becomes patent after 30 hr, numerous tracer molecules appearing in urinary space, without any readily observable changes either in distribution of fixed negative charges (as revealed by colloidal iron and polyethyleneimine) or in structural organization of the glomerulus. Selective permeability of the GBM is progressively restored so that ferritin is almost confined to capillary lumen one month after enzyme injection. We conclude that collagen plays an important part in restricting plasma protein filtration.
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