Lysosomal cysteine proteinases of cathepsins B and H were isolated to a homogeneous state from rat liver by employing Sephadex G-75, DEAE-Sephacel, CM-Sephadex, and Mono S column chromatography. Each of the purified cathepsins B and H was demonstrated to be composed of a mixture of a single-chain form and the processed two-chain form upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). To investigate the proteolytic maturation of lysosomal cathepsins B and H, turnover kinetics of these enzymes were studied by comparing the specific radioactivities of the incorporated [3H]leucine into either the single-chain form or two-chain form in vivo. The specific radioactivity derived from each protein band of lysosomal cathepsin H in SDS-PAGE at 1, 3, 6, 12, 24 and 48 h after the injection of a radiolabel showed that the peak of specific radioactivity of the single-chain form of cathepsin H appeared at 6 h and that after 6 h, the radiolabel was sequentially incorporated into the two-chain form, while the radiolabel in the single-chain form started to gradually decrease, suggesting that the single-chain form was processed to generate the mature enzyme after the enzyme was incorporated into the lysosomes. In contrast, in the case of cathepsin B, the appearance of a radiolabel in the single-chain form or in the two-chain form was observed almost concomitantly without time lag, indicating that the processing of cathepsin B occurred very rapidly in the lysosomes.
HRP-anti LGP107 Fab' and 125I-anti LGP107 IgG were used as probes to study the movement of LGP107 in the endocytic membrane transport system in primary cultured hepatocytes of rats. Following the addition of HRP-anti LGP107 Fab' to the culture medium, the transfer of the antibody conjugate from the cell surface to lysosomes was examined by cell fractionation on Percoll density gradients. The HRP tracer showed a bimodal subcellular distribution, in plasma membrane and lysosomal fractions. The amount of HRP found in the lysosomal fractions became larger as the period of cell incubation was increased. The rate of HRP accumulation in lysosomes was 0.13% of the administered load per hour per 106 cells. When cells were given 125I-anti LGP107 IgG, the antibody was not stored but was rapidly degraded in the lysosomes. The uptake of 125I-IgG by the cells, which was assessed by measuring the TCA-soluble radiolabeled degradation products released into the medium, increased proportionally to the administered concentration of the antibody and to the incubation time. The rate of uptake of the polyvalent 125I-IgG was comparable to that for the uptake of the monovalent HRP-Fab', and remained unchanged even after long exposure of the cells to a saturating concentraton of the polyvalent IgG. This uptake process continued for many hours in the cells exposed to the protein synthesis inhibitor, cyclohex-imide. These results suggest that there is a continuous circulation of LGP107 between the cell surface and lysosomes in hepatocytes.
Cathepsin B, a lysosomal cysteine protease, is synthesized as a glycoprotein with two N-linked oligosaccharide chains, one of which is in the propeptide region while the other is in the mature region. When cultured rat hepatocytes were labeled with [32P] phosphate,32P -labeled cathepsin B was immunoprecipitated only in the proform from cell lysates and medium. Either Endo H or alkaline phosphatase treatment of 32P-labeled procathepsin B demonstrated the acquisition of a mannose 6-phosphate (Man 6-P) residue on high mannose type oligosaccharides. To identify the site of phosphorylation, immunoisolated 32S-or 32P-labeled procathepsin B was incubated with purified lysosomal cathepsin D, since cathepsin D cleaves 48 amino acid residues from the N-terminus of procathepsin B, in which one N-linked oligosaccharide chain was also included [Kawabata, T. etal (1993) J. Biochem 113, 389–394]. Treatment of intracellular 35S-label-ed procathepsin B with a molecular mass of 39-kDa with cathepsin D resulted in the production of the 31-kDa intermediate form, but the 32P-label incorporated into procathepsin B disappeared after treatment with cathepsin D. These results indicate that the phosphorylation of procathepsin B is restricted to an oligosaccharide chain present in the propeptide region. Interestingly, cathepsin B sorting to lysosomes was not inhibited by NH4C1 treatment and about 90%; of the intracellular procathepsin B initially phosphorylated was secreted into the medium without being dephosphorylated intrac-ellularly, and did not bind significantly to cation-independent-Man 6-P receptor, suggesting the failure of Man 6-P-dependent transport of procathepsin B to lysosomes. Additionally, about 50% of the newly synthesized 35S-labeled cathepsin B was retained in the cells in nature forms consisting of a 29-kDa single chain form and a 24-kDa two chain form, while part of the procathepsin B was associated with membranes in a Man 6-P-independent manner. Taken together, these results show that in rat hepatocytes, cathepsin B is targeted to lysosomes by an alternative mechanism(s) other than the Man 6-P-dependent pathway.
Acid phosphatase in rat liver lysosomal contents, C-APase I, was purified about 5,700-fold over the homogenate with 8.0% recovery, to apparent homogeneity as determined from the pattern on polyacrylamide gel electrophoresis in the presence and in the absence of SDS. The purification procedures included; preparation of crude lysosomal contents, DEAE-Sephacel ion exchange chromatography, hydroxylapatite chromatography, and gel filtration with Sephacryl S-300. The enzyme is composed of three identical subunits with an apparent molecular weight of 48K. The enzyme contains about 11% carbohydrate and the carbohydrate moiety was composed of mannose, fucose, N-acetylglucosamine, and N-acetylgalactosamine in a molar ratio of 20:3:11:1. Sialic acid was not detected in the enzyme. Antisera against the purified C-APase I were raised in goat and the C-APase I was rapidly purified with high yield (10%) by using the specific antibodies coupled to Sepharose 6B.
The membrane-association of early biosynthetic form of cathepsin D has been demonstrated in hepatoma cells, and this membrane-association is not mediated by mannose 6-phosphate residues, implying that a mannose 6-phosphate receptor-independent mechanism operates in the sorting of cathepsin D. In this paper, to demonstrate whether cathepsin D is associated with the lysosomal membranes, an in vitro binding experiment was carried out employing lysosomal cathepsin D or microsomal procathepsin D isolated from rat liver. Immunoblotting analysis revealed that an intermediate form of cathepsin D was associated with the lysosomal membranes; this lysosomal membrane-associated cathepsin D was released from the membranes by washing with Na2CO3 (pH 10.6) but not with solutions containing mannose 6-phosphate. This suggested that cathepsin D associates with the membranes by ionic-interaction, and that the membrane-associated cathepsin D resides as a peripheral membrane protein in the lysosomal membrane fraction. To confirm that the intermediate form of cathepsin D specifically interacts with the lysosomal integral membrane proteins, the lysosomal membrane fraction was treated with trypsin and the binding experiment was conducted. The result showed that the binding capacity of cathepsin D to the lysosomal membranes was apparently abolished and cathepsin D did not rebind to the membranes. These data suggest that the intermediate form of cathepsin D is preferentially recognized by the lysosomal membranous protein which complements the mannose 6-phosphate receptor-dependent intracellular sorting mechanism.
