Degradation of short and long lived proteins in isolated rat liver lysosomes. Effects of pH, temperature, and proteolytic inhibitors

Most previous studies on inhibitors of lysosomal protein breakdown have been performed on isolated or cultured cells or on perfused organs. We have tested various inhibitors of proteolysis on lysosomes isolated from livers of rats injected with [14C]leucine 15 min (short labeling time) and 16 h (long labeling time) before killing. Intact lysosomes were incubated with different inhibitors (leupeptin, propylamine, E-64, pepstatin, and chloroquine) in increasing concentrations. None of these caused more than a 40-75% inhibition of proteolysis irrespective of labeling protocol. Chloroquine was the most effective inhibitor, followed by leupeptin, propylamine, E-64, and pepstatin. When lysosomes were incubated with various combinations of inhibitors, including a weak base and an enzyme inhibitor, a somewhat higher inhibition (86%) was obtained. To assess if lysosomes are active in the degradation of both short and long lived proteins, lysosomes were isolated from livers of rats labeled with [14C]leucine for various time intervals. The highest fractional proteolytic rates were seen for short lived proteins. If the recovery of the isolated lysosomes is taken into consideration, about 80% (short labeling time) and 90% (long labeling time) of the total proteolysis in the homogenate could be accounted for by lysosomes. Isolated Golgi, mitochondrial, and microsomal fractions displayed negligible proteolytic activities. The cytosol contributed one-fifth of the total protein breakdown of short lived proteins, whereas insignificant proteolysis was recovered in the cytosolic fraction following long time labeling. Accordingly, we propose that 1) lysosomal inhibitors do not completely suppress proteolysis in isolated lysosomes and that 2) both short and long lived proteins are degraded in lysosomes.     

Evidence that lysosomes are not involved in the degradation of myofibrillar proteins in rat skeletal muscle.

To examine the role of lysosomes in the degradation of skeletal-muscle myofibrillar proteins, we measured the release of N tau-methylhistidine from perfused muscle of starved and fed rats in the presence or absence of agents that inhibit lysosomal proteinase activity. After 1 day of starvation, the release of N tau-methylhistidine by perfused muscle of 4-, 8- and 24-week-old rats increased by 322, 159 and 134% respectively. On the other hand, total protein breakdown, assessed by tyrosine release, increased by 62, 20 and 20% respectively. Inhibitors of lysosomal proteinases as well as high concentrations of insulin or amino acids failed to diminish the release of N tau-methylhistidine by perfused muscle of starved and fed rats, despite a 25-35% inhibition of total protein breakdown. The data strongly suggest that the complete breakdown of myofibrillar proteins occurs via a non-lysosomal pathway. They also suggest that total proteolysis, which primarily reflects non-myofibrillar protein breakdown, occurs at least in part within lysosomes.     

Macrophage endosomes contain proteases which degrade endocytosed protein ligands

Rabbit alveolar macrophages rapidly internalize and degrade mannosylated bovine serum albumin (125I-mannose-BSA). Trichloroacetic acid-soluble degradation products appear in the cells as early as 6 min after uptake at 37 degrees C, and in the extracellular medium after 10 min. Incubation of endocytic vesicles containing this ligand in isotonic buffers at pH 7.4 + ATP resulted in intravesicular proteolysis, which was inhibited by monensin, nigericin, or ammonium chloride. At pH 5.0, degradation proceeded rapidly and was abolished by lysis of the vesicles with 0.1% Triton X-100. Readdition of lysosomes to the incubation mixture did not increase the rate of prelysosomal degradation. Proteolysis of 125I-mannose-BSA was optimal at pH 4.5, and inhibited by low concentrations of the cathepsin D inhibitor pepstatin A. After subcellular fractionation of the macrophages on Percoll gradients, 125I-mannose-BSA sedimented with prelysosomal vesicles and was not transported to secondary lysosomes. Addition of pepstatin A to extracellular medium during internalization of prebound 125I-mannose-BSA partially inhibited degradation of ligand, and resulted in transfer of undegraded 125I-mannose-BSA to lysosomes after 20 min. Using 125I-bovine serum albumin as a substrate for the protease in the presence of 0.1% Triton X-100, we have shown that as much as 36% of the total pepstatin A-sensitive activity sediments with nonlysosomal membranes. After intraendosomal iodination using lactoperoxidase, a labeled protease was isolated by affinity chromatography on pepstatin-agarose. The labeled protease, which had a subunit size of 46 kDa, was detected in endocytic vesicles after 5 min of internalization. These results suggest that a cathepsin D-like protease is responsible for the degradation of 125I-mannose-BSA in macrophages, and that this ligand is degraded in a prelysosomal vesicle.     

Quantitative aspects of the uptake and degradation of lysozyme in the rat kidney in vivo

Uptake and degradation of lysozyme in the rat kidney were studied in vivo. The protein was labeled with 125I by way of a moiety (tyramine-cellobiose or 'TC') which remained trapped inside the cells even after proteolysis of the peptide chain (in contrast, the label from conventionally labeled proteins escapes after degradation). Following the injection of 'trapped-label' lysozyme, the radioactivity in the kidneys represented the total amount of lysozyme that was taken up during the experiment. Proteolysis could be followed by determining the amount of acid-soluble degradation products. By adding the radioactivity in the urine to that in the kidneys, a measure of the total filtered load was obtained. When only a trace dose of 125I-labeled TC lysozyme was injected into rats, the amount of radioactivity in the kidneys increased on average by 0.09% per min, after the concentration in the blood had become nearly stable. After 100 min, 30% of the injected dose was recovered in the kidneys. The labeled protein was degraded to acid-soluble molecules of Mr less than 1000. There was apparently a 'lag period' between the endocytosis in the kidneys and the start of degradation. 40 min after the injection of a trace dose, about 0.6% of the 'trapped-label' lysozyme in the kidneys was degraded per min.; subsequently, there was a decline in the fraction which was degraded per min. The amount of lysozyme in the urine increased after the injection of increasing amounts of lysozyme, showing that the capacity of the uptake mechanism was being exceeded, but truly saturating levels of lysozyme could not be reached in vivo.     

Rat muscle protein turnover and redox state in progressive diabetes

Protein synthesis and degradation, and redox state were measured in soleus and extensor digitorum longus muscles of rats up to 12 days after injection of streptozotocin. Muscle growth was slower in these animals apparently due to slower protein synthesis throughout the duration of diabetes. Up to day 4 after injection of streptozotocin or withdrawal of insulin from treated, diabetic animals, the muscle ratio of lactate/pyruvate, an indicator of the cytoplasmic NAD+ redox couple, was lower and protein degradation was faster than in control muscles. Thereafter, the ratio of lactate/pyruvate was greater and protein degradation was slower than in size- or age-matched control muscles. Insulin treatment in vitro or in vivo increased lactate/pyruvate and decreased proteolysis. Therefore, in muscles of streptozotocin-diabetic rats, the initial increase and later fall in proteolysis, and the inhibition of proteolysis by insulin, may correlate with opposite changes in NADH/NAD+.     

CELL POPULATION CHANGES IN THE INTESTINAL MUCOSA OF PROTEIN-DEPLETED OR STARVED RATS : II. Changes in Cellular Migration Rates

The effect of protein-free and starvation diets on the migration of cells from the crypts onto and up the villi of the rat ileum was studied. Rats starved for 3, 7, or 10 days or fed a protein-free diet (PFD) for 3, 7, or 11 wk were injected with thymidine-³H and sacrificed at timed intervals. The time required for the labeled cells to first appear on the villi of experimental animals was longer than in the controls. This was the result of an elongated cycle in the protein-depleted animals and a lengthening of the maturation period in both the starved and protein-depleted animals. Determination of the distance which labeled cells had migrated up the villi in control and experimental animals, after thymidine-³H injection, indicated that cells in animals starved for 7 days migrated more rapidly than those in the fed controls, while those of 10-day starved animals moved more slowly. The cells of animals fed PFD for 3 wk migrated up the villi more rapidly, those of animals depleted for 7 wk migrated at the same time rate, and those of 11-wk PFD animals migrated more slowly than the fed controls. There is apparently no correlation between the cell cycle time in the crypt cells and the rate of migration of cells up the villus.     

A selective pathway for degradation of cytosolic proteins by lysosomes

A lysosomal pathway of proteolysis is selective for cellular proteins containing peptide sequences biochemically related to Lys-Phe-Glu-Arg-Gln (KFERQ). This pathway is activated in confluent cultured cells that are deprived of serum growth factors and in certain tissues of fasted animals. We have reconstituted this lysosomal degradation pathway in vitro. Transport into lysosomes requires a KFERQ-like sequence in the substrate protein and uptake and/or degradation is stimulated by ATP. A member of the heat shock 70 kDa protein family, the 73 kDa constitutive heat shock protein, binds to KFERQ-like peptide regions within proteins and, in some as yet unidentified manner, facilitates transfer of the proteins into lysosomes. Several possible mechanisms of selective protein transport into lysosomes are discussed.     

The relationship between autophagy and the intracellular degradation of asialoglycoproteins in cultured rat hepatocytes

The relationship between autophagy and the intracellular distribution of endocytosed asialoorosomucoid was studied in cultured rat hepatocytes. Overt autophagy was induced by shifting the cells to a minimal salt medium. Incubation in minimal salt medium led to the formation of buoyant lysosomes at the expense of denser lysosomes manifested as a dual distribution of these organelles in Nycodenz gradients. Asialoorosomucoid was labeled with 125I-tyramine cellobiose. The labeled degradation products formed from this ligand are trapped at the site of degradation and may therefore serve as markers for the subgroup of lysosomes involved in the degradation. In control cells the degradation of the ligand was initiated in a light prelysosomal compartment and continued in denser lysosomes. In cells with high autophagic activity, the degradation of labeled asialoorosomucoid took place exclusively in a buoyant group of lysosomes. These results suggest that degradation of endocytosed ligand takes place in the same secondary lysosomes as substrate sequestered by autophagic mechanisms. These light lysosomes represent a subgroup of active lysosomes which are gradually recruited from dense bodies. Data are also presented that indicate that insulin may prevent the change in buoyant density brought about by incubation in deficient medium.     

Identification of fibroblasts as a major site of albumin catabolism in peripheral tissues

Rat serum albumin has been labeled with dilactitol-125I-tyramine, (125I-DLT) a radioactive tracer which remains entrapped within lysosomes following cellular uptake and degradation of the carrier protein. Similar kinetics of clearance from the rat circulation were observed for albumin labeled conventionally with 125I or 125I-DLT-albumin, both proteins having circulating half-lives of approximately 2.2 days. In contrast, the recovery of whole body radioactivity had half-lives of approximately 2.2 and 5.1 days, respectively, for the two protein preparations, indicating substantial retention of degradation products derived from catabolism of 125I-DLT-albumin. Measurement of total and acid-soluble radioactivity in tissues 2 or 4 days after injection of 125I-DLT-albumin revealed that skin and muscle accounted for the largest fraction (50-60%) of degradation products in the body. Fibroblasts were identified by autoradiography as the major cell type containing radioactive degradation products in skin and muscle. Fibroblasts were isolated from skin by collagenase digestion, followed by density gradient centrifugation. The amount of acid-soluble radioactivity recovered in these cells was in excellent agreement with that predicted based on acid precipitation of solubilized whole skin preparations. These studies demonstrate for the first time that fibroblasts are a major cell type involved in the degradation of albumin in vivo.     

Intracellular transport of endocytosed proteins in rat liver endothelial cells.

1. Receptor-mediated endocytosis of mannose-terminated glycoproteins in rat liver endothelial cells has been followed by means of subcellular fractionation and by immunocytochemical labelling of ultrathin cryosections after intravenous injection of ovalbumin. For subcellular-fractionation studies the ligand was labelled with 125-tyramine-cellobiose adduct, which leads to labelled degradation products being trapped intracellularly in the organelle where the degradation takes place. 2. Isopycnic centrifugation in sucrose gradients of a whole liver homogenate showed that the ligand is sequentially associated with three organelles with increasing buoyant densities. The ligand was, 1 min after injection, recovered in a light, slowly sedimenting vesicle and subsequently (6 min) in larger endosomes. After 24 min the ligand was recovered in dense organelles, where also acid-soluble degradation products accumulated. 3. Immunocytochemical labelling of ultrathin cryosections showed that the ligand appeared rapidly after internalization in coated vesicles and subsequently in two larger types of endosomes. In the 'early' endosomes (1 min after injection) the labelling was seen closely associated with the membrane of the vesicle; after 6 min the ligand was evenly distributed in the lumen. At 24 min after injection the ligand was found in the lysosomes. 4. A bimodal distribution of endothelial cell lysosomes with different buoyant densities was revealed by centrifugation in iso-osmotic Nycodenz gradients, suggesting that two types of lysosomes are involved in the degradation of mannose-terminated glycoproteins in liver endothelial cells. Two populations of lysosomes were also revealed by sucrose-density-gradient centrifugation after injection of large amounts of yeast invertase. 5. In conclusion, ovalbumin is transferred rapidly through three endosomal compartments before delivering to the lysosomes. The degradation seems to take place in two populations of lysosomes.     

Activation of Ras and the mitogen-activated protein kinase pathway promotes protein degradation in muscle cells of Caenorhabditis elegans

To discover and study intracellular signals that regulate proteolysis in muscle, we have employed transgenic strains of Caenorhabditis elegans that produce a soluble LacZ reporter protein limited to body-wall and vulval muscles. This reporter protein is stable in well-fed wild-type animals, but its degradation is triggered upon a shift to 25 degrees C in a strain carrying a temperature-sensitive activating mutation in the Ras oncogene homologue let-60. These mutants are not physiologically starved, inasmuch as growth rates are normal at 25 degrees C. Ras-induced degradation is not prevented by the presence of cycloheximide added at or before the temperature shift and thus uses preexisting proteolytic systems and signaling components. Furthermore, degradation is triggered when adult animals are shifted to conditions of 25 degrees C, confirming that Ras acutely promotes protein degradation in muscles whose developmental history is normal. Reduction-of-function mutations in the downstream protein kinase Raf (lin-45), MEK (mek-2), or mitogen-activated protein kinase (MAPK) (mpk-1) prevent Ras-induced protein degradation, whereas activated MPK-1 is sufficient to trigger degradation, indicating that this kinase cascade is the principal route by which Ras signaling triggers protein degradation in muscle. This pathway is activated in hypodermal cells by the LET-23 epidermal growth factor receptor homologue, but an activating mutation in let-23 does not promote proteolysis in muscle. Starvation-induced LacZ reporter degradation is unaffected by reduction-of-function mutations in Ras, Raf, MEK, or MAPK, implying that Ras activation and starvation trigger proteolysis by mechanisms that are at least partially independent. This is the first evidence that Ras-Raf-MEK-MAPK signaling activates protein degradation in differentiated muscle.     

Physiological consequences of starvation in Pseudomonas putida: degradation of intracellular protein and loss of activity of the inducible enzymes of L-arginine catabolism.

We investigated the degradation of radioisotopically labeled intracellular protein in starved, intact cells of Pseudomonas putida P2 (ATCC 25571) and the regulation of this process. Intracellular protein isotopically labeled with L-[4,5-3H]leucine during log-phase growth at 30 C is degraded at rates of 1 to 2%/h in log-phase cells and 7 to 9%/h in starved cells. Rifampin, chloramphenicol, and tosyllysine chloromethylketone lower the rate of protein degradation by starved cells. Addition to starved cells of a nutrient upon which the culture is induced for growth rapidly lowers the rate of protein degradation from 7 to 9%/h to less than 1.5%/h. A nutrient that is oxidized but that cannot immediately support growth also lowers the rate of starvation-induced protein degradation. Proteolytic activity of cell extracts requires a divalent metal ion and may be inhibited up to 60% by tosyllysine chloromethylketone or p-toluenesulfonyl fluoride. Rifampin and chloramphenicol have no effect. In contrast to intact cells, extracts of growing or starving cells degrade protein at equivalent rates. We also investigated the stabilities of the inducible transport system and of four inducible intracellular enzymes of L-arginine catabolism. These include: the membrane-associated, L-arginine-specific transport system; L-arginine oxidase (oxidase); alpha-ketoarginine decarboxylase (decarboxylase); gamma-guanidinobutyraldehyde dehydrogenase ( dehydrogenase); and gamma-guanidinobutyrate amidinohydrolase (hydrolase). In starved cells, the rates of loss of activities were: transport and dehydrogenase activities, stable; oxidase and decarboxylase activities, 20 to 30%/h; hydrolase activity, 5 to 8%/h. Chloramphenicol decreases the rate of loss of oxidase, decarboxylase, and hydrolase activity, whereas p-toluenesulfonyl fluoride lowers the rate of loss of decarboxylase but not of oxidase or hydrolase activity. Addition to starved cells of a nutrient for which they are already induced for growth (e.g., malate, a noninducer of arginine catabolic enzymes) decreases the rate of loss of oxidase and decarboxylase activity but not that of the hydrolase.     

Autophagy maintains cardiac function in the starved adult

To examine the functional significance and detailed morphological characteristics of starvation-induced autophagy in the adult heart, we starved green fluorescent protein (GFP)-microtubule-associated protein 1 light chain 3 (LC3) transgenic mice for up to 3 days. Electron microscopy revealed that, after as little as 12 hours of starvation, round and homogenously electron-dense lipid droplet-like vacuoles appeared in cardiomyocytes. These were determined to be lysosomes based on cathepsin D immunopositivity and acid phosphatase activity. The numbers of these lysosomes increased with starvation time, and typical autolysosomes with intracellular organelles destined for degradation appeared and increased in number at later times during the starvation period. Myocardial expression of the autophagy-related proteins LC3-II, cathepsin D, and ubiquitin increased, while myocardial ATP content decreased, as the starvation interval proceeded. Treatment with bafilomycin A1, an autophagy inhibitor, did not affect cardiac function in normally fed mice, but it significantly depressed cardiac function and caused significant left ventricular dilatation in the mice starved for 3 days. Cardiomyocytes from starved mice treated with bafilomycin A1 showed marked accumulation of lysosomes, and the myocardial amino acid content, which increased during starvation in normally fed mice, as well as the myocardial ATP content, were severely reduced, which likely contributed to the cardiac dysfunction. The present findings suggest autophagy plays a critical role in the maintenance of cardiac function during starvation in the adult.     

Role of thiols, pH and cathepsin D in the lysosomal catabolism of serum albumin.

Attempts were made to assess the role of thiols and to determine the cathepsins involved in the degradation of serum albumin in mouse liver and kidney lysosomes. Unlike cysteine or beta-mercaptoethanol, reduced glutathione (GSH) did not stimulate the degradation of formaldehyde-treated albumin in liver lysosomes, suggesting that the tripeptide did not penetrate the membrane. However, GSH was a much more effective stimulant of proteolysis in kidney lysosomes than was cysteine at low concentrations, and the effect was saturable at 1-2 mM concentrations. Thiols did not stimulate proteolysis in lysosomes when the disulphide bonds of albumin were reduced and alkylated, suggesting that the stimulatory effects were solely due to disulphide-bond reduction in protein substrates. Results obtained with thiols and iodoacetamide suggested that albumins denatured by disulphide-bond reduction and alkylation, disulphide-bond reduction without alkylation, or by treatment with 8 M-urea, were all degraded primarily by cathepsin D in lysosomes, but formaldehyde-denatured albumin was attacked by thiol proteinases. These findings correlated well with studies on the degradation of these proteins by rat liver lysosome (tritosome) extracts. Studies with the proteinase inhibitors leupeptin and pepstatin and the stimulatory effects of thiols in these extracts suggested that formaldehyde-denatured albumin was degraded primarily by the thiol proteinases, but that native albumin or albumins denatured by disulphide-bond reduction or by treatment with 8 M-urea were attacked by cathepsin D. Denaturation of serum albumin by any of the methods used caused a shift in the pH optimum of albumin catabolism by tritosome extracts or by purified cathepsin D from approx. 3-4 to 5-6. These results were discussed in terms of a possible mechanism for the catabolic aspect of serum albumin turnover.     

Metabolism of branched-chain amino acids in starved rats: the role of hepatic tissue

Parameters of branched-chain amino acids (BCAA; leucine, isoleucine and valine) and protein metabolism were evaluated using L-[1-(14)C]leucine and alpha-keto[1-(14)C]isocaproate (KIC) in the whole body and in isolated perfused liver (IPL) of rats fed ad libitum or starved for 3 days. Starvation caused a significant increase in plasma BCAA levels and a decrease in leucine appearance from proteolysis, leucine incorporation into body proteins, leucine oxidation, leucine-oxidized fraction, and leucine clearance. Protein synthesis decreased significantly in skeletal muscle and the liver. There were no significant differences in leucine and KIC oxidation by IPL. In starved animals, a significant increase in net release of BCAA and tyrosine by IPL was observed, while the effect on other amino acids was non-significant. We conclude that the protein-sparing phase of uncomplicated starvation is associated with decreased whole-body proteolysis, protein synthesis, branched-chain amino acid (BCAA) oxidation, and BCAA clearance. The increase in plasma BCAA levels in starved animals results in part from decreased BCAA catabolism, particularly in heart and skeletal muscles, and from a net release of BCAA by the hepatic tissue.     

Response of heterogenous rat liver lysosome populations to starvation and refeeding.

Starvation-induced alterations in liver lysosomes and their recovery pattern following refeeding were investigated. Fasting of adult rats for five days caused an increase in 'free' activities of acid hydrolyses in liver homogenates and loss in sedimentation of one of the heterogenous populations of lysosomes that could be isolated by differential centrifugation. Isopycnic sucrose gradient centrifugation revealed a decrease in the median and modal equilibration densities of all the forms of lysosomes in response to the dietary deprivation. Further, starvation also evoked a distinct bimodal distribution in a population that was rich in acid phosphatases, beta-galactosidase and N-acetyl-beta-glucosaminidase. Realimentation of starved animals for 10 days was found to restore the enzyme levels and the sedimentation characteristics to normal profiles.     

The role of leucine in ketogenesis in starved rats.

The quantitative significance of the conversion in vivo of L-[U-14C]leucine to ketone bodies was determined in rats starved for 3 or 48 h. In animals starved for 3 h, 4.4% of ketone-body carbon is derived from the metabolism of leucine, and in rats starved for 48 h the corresponding value is 2.3%. This conversion occurs rapidly, and the specific radioactivity of ketone bodies in blood is maximal at 2 min after the intravenous injection of labelled leucine for both periods of starvation. The flux of leucine in the blood is 1.01 and 1.04 mumol/min per 100 g body wt. respectively for animals starved for 3 and 48 h. The specific radioactivity of blood ketone bodies was compared at 2 min after the injection of labelled leucine, lysine and phenylalanine. The specific radioactivity was 4-5 fold higher with leucine than with lysine or phenylalanine.     

Control of cell protein catabolism in rat liver. Effects of starvation and administration of cycloheximide.

1. The loss of liver protein occurring in rats starved for 24 h was largely prevented by the administration of repeated doses of cycloheximide, an inhibitor of protein synthesis. Similar effects were produced on tubulin, a 'fixed' liver protein. 2. Starvation accelerated, whereas cycloheximide markedly lowered, the rate of protein radioactivity decay after labelling with [3H]valine or [14C]bicarbonate, indicating that changes in catabolic rates played an important role in the above regulations of liver protein mass. 3. The total activity of several lysosomal hydrolases showed little change in livers of starved rats, but a marked progressive decline developed after the administration of cycloheximide, particularly in the activities of cathepsins B, D and L as well as acid ribonuclease. There was no evidence that these changes might be due to endogenous inhibitors (at least for cathepsin B activity, which fell to less than 30% of the control values) or enzyme leakage into the bloodstream; rather, plasma beta-galactosidase and beta-N-acetylglucosaminidase activities fell progressively during the cycloheximide treatment. 4. Endogenous proteolytic rates, measured in vitro by incubating subcellular preparations from livers prelabelled in vivo with [3H]valine, were markedly decreased in cycloheximide-treated animals. 5. The osmotic fragility of hepatic lysosomes, appreciably enhanced in starved animals, after cycloheximide treatment was found to be even lower than in fed controls. 6. The present data are consistent with the view that in starved animals the loss of liver protein is mostly accounted for by increased breakdown, due, in part at least, to enhanced autophagocytosis. 7. Cycloheximide largely counteracted these effects of starvation, altering the liver from being 'poised' in a proteolytic direction to a protein-sparing condition. The present data suggest that, besides suppression of the autophagic processes, a decrease in the lysosomal proteolytic enzyme system may also play a role in this regulation, and they seem to provide further circumstantial evidence for the existence of co-ordinating mechanisms between protein synthesis and degradation.     

Protein kinase C-dependent inhibition of the lysosomal degradation of endocytosed proteins in rat hepatocytes

We studied the role of protein kinase C (PKC) in the lysosomal processing of endocytosed proteins in isolated rat hepatocytes. We used [14C]sucrose-labeled horseradish peroxidase ([14C]S-HRP) to simultaneously evaluate endocytosis and lysosomal proteolysis. The PKC activator phorbol 12-myristate 13-acetate (PMA) inhibited the lysosomal degradation of [14C]S-HRP (1 microM PMA: 40% inhibition, P<.05), without affecting either the endocytic uptake or the delivery to lysosomes. However, PMA was not able to affect the lysosomal processing of the beta-galactosidase substrate dextran galactosyl umbelliferone. The PKC inhibitors, chelerytrine (Che), staurosporine (St) and G? 6976, prevented PMA inhibitory effect on lysosomal proteolysis. Nevertheless, purified PKC failed to alter proteolysis in [14C]S-HRP-loaded isolated lysosomes, suggesting that intracellular intermediates are required. PMA induced phosphorylation and hepatocyte membrane-to-lysosome redistribution of the myristoylated alanine-rich C kinase substrate (MARCKS) protein, raising the possibility that MARCKS mediates the PKC-induced inhibition of lysosomal proteolysis.