The renal degradation of myelin basic protein peptide 43-88 by two enzymes in different subcellular fractions.

Previous studies have demonstrated that the kidney is the major site for clearance and catabolism of a peptide (residues 43-88) of encephalitogenic or basic protein (BP) derived from central-nervous-system myelin. In the present investigation rat renal tissue was shown to be capable of degrading human BP peptide 43-88 over the pH range 4-11.5 with peaks of activity at pH5 and pH9. The enzymic activity at pH5 was localized mainly to the 5900 g pellet (crude mitochondrial fraction) and, on the basis of its sulphydryl features, was inferred to be cathepsin B. The enzyme activity at pH9 was greatly enriched in the 100 000 g pellet (microsomal brush-border fraction), and its sensitivity to inhibitors suggested that it was a metalloproteinase. The activity at alkaline pH in the 100 000 g pellet was stimulated 3-fold by non-ionic detergents and 20-fold by ATP and polyphosphates. Through a series of experiments the ATP stimulation of the alkaline proteinase activity was concluded to be the result of a reversal of inhibition imposed by the presence of another cationic protein, methylated bovine serum albumin. Inhibition by certain bivalent cations, the irregular effects of chelators and the effects of poly-L-lysine supported this conclusion. These studies indicate the availability of renal enzymes of different types and in different cellular compartments that are capable of degrading BP peptide 43-88. In particular, the relative amounts of bivalent cations, anions and charged proteins and peptides are likely to be major influences on the activity of the alkaline proteinase in vivo. The control of this degradation as well as the features of the smaller fragments of the peptide formed may determine biological and immune events subsequent to the release of this potentially autoantigenic material.