The lysosomal pathway of intracellular proteolysis in liver: regulation by amino acids

Amino Acids in Autophagy: Regulation and Function

Autophagy is a dynamic process in which the eukaryotic cells break down intracellular components by lysosomal degradation. Under the normal condition, the basal level of autophagy removes damaged organelles, misfolded proteins, or protein aggregates to keep cells in a homeostatic condition. Deprivation of nutrients (e.g., removal of amino acids) stimulates autophagy activity, promoting lysosomal degradation and the recycling of cellular components for cell survival. Importantly, insulin and amino acids are two main inhibitors of autophagy. They both activate the mTOR complex 1 (mTORC1) signaling pathway to inhibit the autophagy upstream of the uncoordinated-51 like kinase 1/2 (ULK1/2) complex that triggers autophagosome formation. In particular, insulin activates mTORC1 via the PI3K class I-AKT pathway; while amino acids activate mTORC1 either through the PI3K class III (hVps34) pathway or through a variety of amino acid sensors located in the cytosol or lysosomal membrane. These amino acid sensors control the translocation of mTORC1 from the cytosol to the lysosomal surface where mTORC1 is activated by Rheb GTPase, therefore regulating autophagy and the lysosomal protein degradation.

Chronic social stress alters protein metabolism in juvenile rainbow trout, Oncorhynchus mykiss

When confined in pairs, juvenile rainbow trout (Oncorhynchus mykiss) form dominance hierarchies in which subordinate fish exhibit characteristic physiological changes including reduced growth rates and chronically elevated plasma cortisol concentrations. We hypothesized that alterations in protein metabolism contribute to the reduced growth rate of socially stressed trout, and predicted that subordinate trout would exhibit reduced rates of protein synthesis coupled with increases in protein degradation. Protein metabolism was assessed in dominant and subordinate fish after 4 days of social interaction, and in fish that were separated after 4 days of interaction for a 4 days recovery period, to determine whether effects on protein metabolism recovered when social stress was alleviated. Protein metabolism was assessed in liver and white muscle by measuring the fractional rate of protein synthesis and markers of protein degradation. In the white muscle of subordinate fish, protein synthesis was inhibited and activities of the ubiquitin-proteasome pathway (UPP) and the autophagy lysosomal system (ALS) were elevated. By contrast, the liver of subordinate fish exhibited increased rates of protein synthesis and activation of the ALS. When allowed to recover from chronic social stress for 4 days, differences in protein metabolism observed in white muscle of subordinate fish during the interaction period disappeared. In liver, protein synthesis returned to baseline levels during recovery from social stress, but markers of protein degradation did not. Collectively, these data support the hypothesis that inhibition of muscle protein synthesis coupled with increases in muscle protein breakdown contribute to the reduced growth rates of subordinate rainbow trout.

Chaperone-mediated autophagy: a unique way to enter the lysosome world

All cellular proteins undergo continuous synthesis and degradation. This permanent renewal is necessary to maintain a functional proteome and to allow rapid changes in levels of specific proteins with regulatory purposes. Although for a long time lysosomes were considered unable to contribute to the selective degradation of individual proteins, the discovery of chaperone-mediated autophagy (CMA) changed this notion. Here, we review the characteristics that set CMA apart from other types of lysosomal degradation and the subset of molecules that confer cells the capability to identify individual cytosolic proteins and direct them across the lysosomal membrane for degradation.

Mitophagy and mitochondrial morphology in human melanoma-derived cells post exposure to simulated sunlight

PURPOSE

To assess changes in mitochondrial morphology and mitophagy induced by simulated sunlight irradiation (SSI) and how these changes are modulated by mitochondrial activity and energy source.

MATERIALS AND METHODS

Human malignant amelanotic melanoma A375 cells were pre-treated with either a mitochondrial activity enhancer, uncoupler or were either melanin or glutamine supplemented/starved for 4 hours pre-exposure to sunlight. A Q-Sun Solar Simulator (Q-Lab, Homestead, FL, USA) was employed to expose cells to simulated sunlight. Confocal microscopy imaging of A375 cells co-loaded with mitochondria and lysosome-specific fluorescent dyes was used to identify these organelles and predict mitophagic events.

RESULTS

SSI induces pronounced changes in mitochondrial dynamics and mitophagy in exposed skin cells compared to control and these effects were modified by both glutamine and melanin.

CONCLUSIONS

Mitochondrial dynamics and rate of mitophagy in melanoma cells are sensitive to even short bursts of environmentally relevant SSI. Mitochondrial dynamics, and its modulation, may also play a role in mitophagy regulation, cell survival and proliferation post SSI.

TI-VAMP/VAMP7 and VAMP3/cellubrevin: two v-SNARE proteins involved in specific steps of the autophagy/multivesicular body pathways

During reticulocyte maturation, some membrane proteins and organelles that are not required in the mature red cell are lost. Several of these proteins are released into the extracellular medium associated with the internal vesicles present in multivesicular bodies (MVBs). Likewise, organelles such as mitochondria and endoplasmic reticulum are wrapped into double membrane vacuoles (i.e., autophagosomes) and degraded via autophagy. Morphological, molecular, and biochemical studies have shown that autophagosomes fuse with MVBs forming the so-called amphisomes, a prelysosomal hybrid organelle. SNAREs are key molecules of the vesicle fusion machinery. TI-VAMP/VAMP7 and VAMP3/cellubrevin are two v-SNARE proteins involved in the endocytic and exocytic pathways. We have previously shown that in the human leukemic K562 cells, Rab11 decorates MVBs and it is necessary for fusion between autophagosomes with MVBs. In the present report, we present evidence indicating that VAMP3 is required for the fusion between MVBs with autophagosomes to generate the amphisome, allowing the maturation of the autophagosome, but it does not seem to be involved in the next step, i. e., fusion with the lysosome. On the other hand, we demonstrate that VAMP7 is necessary for this latter event, allowing the completion of the autophagic pathway. Furthermore, VAMP7 and ATPase NSF, a protein required for SNAREs disassembly, participate in the fusion between MVBs with the plasma membrane to release the internal vesicles (i.e., exosomes) into the extracellular medium.

Autophagy induction favours the generation and maturation of the Coxiella-replicative vacuoles

Pathogens evolved mechanisms to invade host cells and to multiply in the cytosol or in compositionally and functionally customized membrane-bound compartments. Coxiella burnetii, the agent of Q fever in man is a Gram-negative gamma-proteobacterium which multiplies in large, acidified, hydrolase-rich and fusogenic vacuoles with phagolysosomal-like characteristics. We reported previously that C. burnetii phase II replicative compartments are labelled by LC3, a protein specifically localized to autophagic vesicles. We show here that autophagy in Chinese hamster ovary cells, induced by amino acid deprivation prior to infection with Coxiella increased the number of infected cells, the size of the vacuoles, and their bacterial load. Furthermore, overexpression of GFP-LC3 or of GFP-Rab24 - a protein also localized to autophagic vacuoles - likewise accelerated the development of Coxiella-vacuoles at early times after infection. However, overexpression of mutants of those proteins that cannot be targeted to autophagosomes dramatically decreased the number and size of the vacuoles in the first hours of infection, although by 48 h the infection was similar to that of non-transfected controls. Overall, the results suggest that transit through the autophagic pathway increases the infection with Coxiella by providing a niche more favourable to their initial survival and multiplication.

Mechanisms of caspase-independent neuronal death: energy depletion and free radical generation

Cultured rat embryonic cortical neurons undergo apoptosis when treated with the topoisomerase-I inhibitor camptothecin. Pharmacological or molecular caspase inhibition prevents apoptosis, but the neurons still die in a delayed nonapoptotic manner. Here we examine the mechanisms leading to such caspase-independent death, focusing on events related to mitochondrial malfunction, which accompanies this delayed death. Given that mitochondria are the major source of ATP in primary neurons, we examined the cellular energy state. Mitochondrially generated ATP was specifically reduced in neurons treated with camptothecin and Boc-aspartyl-fluoromethylketone. Augmentation of cellular ATP by manipulation of the glucose content in the cultures led to an increase in survival specifically in delayed caspase-independent but not early caspase-dependent death. As another possible consequence of mitochondrial malfunction, we found an induction of reactive oxygen species in delayed death. The free radical scavenger Tempol, but not other classes of antioxidants, reduced oxidative stress and promoted survival. Other potential events known to be a direct or indirect consequence of mitochondrial dysfunction, such as the induction of autophagy, release of apoptosis-inducing factor, or opening of the mitochondrial permeability transition pore, were not found to play a significant role in caspase-independent neuronal death. Combining the strategies of increasing intracellular ATP and reducing free radicals led to an additive increase in neuronal survival. We conclude that energy failure and free radical generation contribute to caspase-independent neuronal death. Both could represent potential targets for therapeutic interventions complementary to caspase inhibition.

Insulin inhibition of protein degradation in cells expressing wild-type and mutant insulin receptors

The mechanism by which insulin decreases protein degradation is unknown. We examined insulin binding and degradation (125I[A14]insulin) and protein degradation (3H-leucine labeling) in Chinese hamster ovary (CHO) cells transfected with wild-type (WI) and mutant human insulin receptors. The deltaExon-16 mutant is missing the juxtamembrane domain that mediates endocytosis. The delta343 mutant receptor lacks the tyrosine kinase structural domain but retains the juxtamembrane internalization domain. The mutant deltaNPEY lacks the single NPEY sequence located 16 residues after the end of the transmembrane domain. Null transfected cells (NEO) not expressing human receptors were studied as controls. The WT and deltaNPEY cells equivalently internalized and degraded insulin; delta343 cells internalized and degraded insulin, but at a reduced rate; deltaExon-16 cells internalized and degraded significantly less insulin than the other mutants; NEO cells showed essentially no internalization and degradation. In contrast, all cell types showed the same efficacy at inhibition of protein degradation, albeit at different potencies. These results suggest insulin actions are mediated by multiple and redundant effector systems, but that receptor tyrosine kinase activity is not required for inhibition of protein degradation.

Inhibition of proteasome activity by selected amino acids

Cellular protein homeostasis is a balance between synthesis and degradation. Protein degradation is regulated by hormones (eg, insulin) and nutrients (eg, amino acids). Certain amino acids are capable of decreasing cellular protein degradation, with evidence that this is mediated through altered lysosomal function. However, proteasomes, the major cytosolic protein degrading machinery, are being shown to play a central role in the control of protein turnover in the cell. In this study we show that the amino acids, isoleucine, leucine, tyrosine, phenylalanine, tryptophan, lysine, and arginine are capable of inhibiting the chymotrypsin-like activity of the proteasome in a dose-dependent manner. Leucine, tyrosine, and phenylalanine have a substantial effect at normal serum concentrations. The effect was greater in a proteasome preparation derived from muscle compared to a similar preparation from liver. On the assumption that amino acid-induced alterations in cellular protein degradation reflect the inhibitory changes in proteasomal activity shown here, we may conclude that amino acid control of cellular protein degradation is mediated, at least in part, through proteasomes.

Vacuolar import of proteins and organelles from the cytoplasm

Many cellular processes require a balance between protein synthesis and protein degradation. The vacuole/lysosome is the main site of protein and organellar turnover within the cell due to its ability to sequester numerous hydrolases within a membrane-enclosed compartment. Several mechanisms are used to deliver substrates, as well as resident hydrolases, to this organelle. The delivery processes involve dynamic rearrangements of membrane. In addition, continual adjustments are made to respond to changes in environmental conditions. In this review, we focus on recent progress made in analyzing these delivery processes at a molecular level. The identification of protein components involved in the recognition, sequestration, and transport events has begun to provide information about this important area of eukaryotic cell physiology.

Insulin acts intracellularly on proteasomes through insulin-degrading enzyme

Insulin decreases cellular protein degradation, but the mechanism of this action is poorly understood. We have shown that insulin can have an inhibitory effect on the action of the proteasome in vitro, which requires the presence of insulin degrading enzyme (IDE). In this study we have used an antibody which inhibits the activity of IDE to show that IDE is required for insulin inhibition of protein degradation in intact cells. The anti-IDE antibody blocked the insulin effect on cellular degradation of proteins prelabeled with radioactive amino acids. The anti-IDE antibody also decreased insulin inhibition of proteasome degradation of a specific substrate in intact cells. These data suggest that insulin works intracellularly via IDE to inhibit protein degradation by the proteasome. Thus, IDE may function as an intracellular mediator for insulin effects on protein degradation. This is a novel signal transduction mechanism for peptide hormones.

Thyroid hormones, procollagen III peptide, body composition and basal metabolic rate in euthyroid individuals

We examined 103 euthyroid men and women within a wide range of body weights and ages. Fat free mass (FFM) and body fat (BF) were determined with the total body potassium technique, basal metabolic rate (BMR) by indirect calorimetry and serum concentrations of thyroid hormones (free and total T3 and T4) and the aminoterminal propeptide of collagen III (pIIIp) by immunoassays. BMR was positively related to FFM, BF, total T3, the free T3/free T4 ratio and pIIIp, and negatively to free T4 (men) and to the ratios free T4/total T4 and free T3/total T3. pIIIp was as strongly related to BMR as to total T3. It is suggested that pIIIp may serve as an indicator of peripheral energy expenditure. The negative relationship between BMR and free T4 was unexpected and different to the situation in hypo- and hyperthyreosis where BMR and thyroid hormone are positively related. Our hypothesis is that euthyroid subjects with low serum free thyroid hormone concentrations and comparatively high BMR may have high intracellular thyroid hormone concentrations.

Inhibition of hepatic proteolysis by insulin. Role of hormone-induced alterations of the cellular K+ balance

1. Proteolysis was measured as [3H]leucine release from isolated perfused livers from rats, which had been labeled in vivo by an intraperitoneal injection of [3H]leucine about 16 h prior to the perfusion experiment. In livers from fed rats, insulin (35 nM) inhibited [3H]leucine release by 24.5 +/- 1.3% (n = 15) and led to an amiloride-sensitive, bumetanide-sensitive and furosemide-sensitive net K+ uptake of 5.53 +/- 0.31 mumol.g-1 (n = 15). Both the insulin effects on net K+ uptake and on [3H]leucine release were diminished by about 65% or 55% in presence of furosemide (0.1 mM) or bumetanide (5 microM), respectively. The insulin-induced net K+ uptake was virtually abolished in the presence of amiloride (1 mM) plus furosemide (0.1 mM). 2. In perfused livers from 24-h-starved rats, both the insulin-stimulated net K+ uptake and the insulin-induced inhibition of [3H]leucine release were about 80% lower than observed in experiments with livers from fed rats. The insulin effects on K+ balance and [3H]leucine release were not significantly influenced in the presence of glycine (2 mM), although glycine itself inhibited [3H]leucine release by 30.3 +/- 0.3% (n = 4) and 13.8 +/- 1.2% (n = 5) in livers from starved and fed rats, respectively. When livers from fed rats were preswollen by hypoosmotic perfusion (225 mOsmol.l-1), both the insulin-induced net K+ uptake and the inhibition of [3H]leucine release were diminished by 50-60%. 3. During inhibition of [3H]leucine release by insulin, further addition of glucagon (100 nM) led to a marked net K+ release from the liver (3.82 +/- 0.24 mumol.g-1), which was accompanied by stimulation of [3H]leucine release by 16.4 +/- 4.6% (n = 4). 4. Ba2+ (1 mM) infusion led to a net K+ uptake by the liver of 3.2 +/- 0.2 mumol.g-1 (n = 4) and simultaneously inhibited [3H]leucine release by 12.4 +/- 1.7% (n = 4). 5. There was a close relationship between the Ba2+ or insulin-induced net K+ uptake and the degree of inhibition of [3H]leucine release, even when the K+ response to insulin was modulated by bumetanide, furosemide, glucagon, hypotonic or glycine-induced cell swelling or the nutritional state. 6. The data suggest that the insulin-induced net K+ uptake involves activation of both NaCl/KCl cotransport and Na+/H+ exchange.(ABSTRACT TRUNCATED AT 400 WORDS)

Hepatic metabolism of colloidal gold-low-density lipoprotein complexes in the rat: evidence for bulk excretion of lysosomal contents into bile

Rats were treated with 17 alpha-ethinyl estradiol to induce high levels of low-density lipoprotein receptors in hepatocytes. When these rats were given intravenous injections of low-density lipoprotein-colloidal gold complexes, most of the gold (labeled with 195Au) appeared to be taken up by Kupffer cells, as were complexes of colloidal gold with albumin or polyvinylpyrrolidone. However, when these rats were also administered gadolinium chloride, which blocks Kupffer cell activity, most of the low-density lipoprotein-gold (but not gold complexed with albumin or polyvinylpyrrolidone) was taken up into hepatocytes by receptor-mediated endocytosis and concentrated in peribiliary lysosomes, as determined by electron microscopy. Colloidal gold taken up as a complex with low-density lipoprotein was excreted into the feces via the common bile duct at a maximal rate of about 5% daily, 4 to 12 days after injection. Thereafter, the rate of gold excretion fell off until reaching a plateau after 3 weeks. At this late time, most of the colloidal gold was shown by electron microscopy to be in Kupffer cells, whereas earlier (6 days after injection) it was contained mainly in older hepatocytic lysosomes, identified by lipofuscin granules. It is concluded that, in rats, hepatocytic lysosomes empty most of their contents into bile every week or two, apparently by exocytosis.

Stimulation of autophagic protein degradation by nutrient deprivation in a differentiated murine teratocarcinoma (F9 12-1a) cell line

We have evaluated the participation of the lysosomal degradation pathway in the increased protein degradation induced by nutrient deprivation in transformed cells. To this end we used a clone, 12-1a, derived from a murine teratocarcinoma cell line (F9 12-1) induced to differentiate by culture in retinoic acid. Culture of 12-1a cells, prelabeled with L-[U-14C]valine, in nutrient-deprived medium (Hanks' balanced salt solution plus Ca++) stimulated the protein degradation rate from 0.9% hr to 1.4% hr. Morphometric analysis demonstrated that during nutrient deprivation, the volume density of lysosomes increased 3-fold; the numerical density of lysosomes increased 2-fold; the mean area of lysosomal profiles increased 1.7-fold (1.40 microns2 vs 0.81 microns2). The volume density and numerical density of the dense bodies tended to decrease by approximately 60% without any change in the mean volume of the dense bodies. These data indicate that nutrient deprivation increases protein degradation in transformed cells by increasing the sequestration of cytoplasm into the lysosomes. The decrease in the number of dense bodies indicates that these structures (also termed residual bodies) are functional in transformed cells and merge with the lysosomes to provide more degradative enzymes to enhance proteolysis. This study provides direct evidence that serum factors and nutrients play a crucial role in modulation of lysosomal protein degradation in transformed cells.

The amounts of rat liver cyclic AMP-dependent protein kinase I and II are differentially regulated by diet

1. The fluctuations in rat hepatocyte volume and protein content in response to dietary perturbations (starvation, protein restriction, refeeding) were accompanied by corresponding fluctuations in the amount of the regulatory (R) and catalytic (C) subunits of cyclic AMP-dependent protein kinase. Thus the intracellular concentration of this key enzyme was adjusted to be near constant. 2. The adjustment of cellular R was accomplished almost exclusively by regulating cytosolic RI (R subunit of type I kinase). The preferential down-regulation of cytosolic RI in response to starvation/protein restriction indicates that particulate RI and cytosolic as well as particulate RII are more resistant to breakdown during general catabolism in the hepatocyte. 3. The diet-induced fluctuations of kinase subunits were uniformly distributed in all populations of parenchymatous hepatocytes, regardless of their size and density. It is thus possible to isolate hepatocytes with uniformly altered RI/RII ratio from livers of rats with different feeding regimens. 4. The binding of endogenous cyclic AMP to RI and RII was similar in livers with high RI/RII ratio (fed rats) and low RI/RII ratio (fasted rats) as well as in hepatocytes isolated from fasted rats. Under the conditions of the experiment (short-term stimulation by glucagon), therefore, neither the dietary state nor the RI/RII ratio seemed to affect the apparent affinity of the isoreceptors for cyclic AMP. However, RI appeared to show a slightly higher co-operativity of intracellular cyclic AMP binding than did RII in all states.

Hepatocytic lipoprotein receptors and intracellular lipoprotein catabolism

Hepatocytes, as the major site of synthesis and terminal catabolism of plasma lipoproteins, exert the major regulatory influence on the concentration of atherogenic lipoproteins in blood plasma and may thereby influence the rate of atherogenesis. The LDL receptor on the microvillous sinusoidal surface of hepatocytes mediates the catabolism of remnants of triglyceride-rich lipoproteins and LDL. Binding of VLDL remnants to the receptor, mediated by apo E, is of very high affinity and presumably multivalent, whereas binding of LDL, mediated by apo B-100, is monovalent and of lower affinity, accounting for the much longer residence time of the latter in the blood. The magnitude of the influx of lipoprotein particles into hepatocytic endosomal compartments dwarfs that of other macromolecules undergoing receptor-mediated endocytosis and terminal catabolism in lysosomes of these cells. The intracellular compartments and processing steps in hepatocytic lipoprotein uptake and degradation are essentially the same as those described for other ligands in the liver and other cells. Receptors with bound lipoproteins migrate into coated pits which become coated vesicles. These vesicles uncoat and fuse to form CURL vesicles and tubules near the cell surface where most receptors are recycled, presumably via receptor-rich appendages that become separated from the vesicles. CURL vesicles become mature MVBs as they migrate to the Golgi/bile canalicular pole of hepatocytes, where they fuse with putative Golgi-derived primary lysosomes and are transformed into heterophagic secondary lysosomes. MVBs also contain a receptor-rich appendage that may recycle some receptors directly to the cell surface or through adjacent Golgi compartments. Dilated ends of trans-Golgi cisternae contain nascent VLDL undergoing packaging for secretion following their synthesis and assembly in the endoplasmic reticulum. Because these "forming secretory vesicles" resemble remnant-filled MVBs, occur in a similar location in the Golgi area of hepatocytes and coisolate in centrifugal fractions of liver homogenates, there has been considerable confusion about the identity of these compartments. With the aid of specific endocytic and exocytic markers, highly purified and morphologically intact endosomal and Golgi compartments can now be obtained from rat liver homogenates. The availability of these and similar fractions of defined purity should facilitate investigation of the hepatocytic processing of endocytosed and secreted macromolecules. Although chylomicron remnants are also taken up by receptor-mediated endocytosis, the nature of the hepatocytic remnant receptor remains elusive.(ABSTRACT TRUNCATED AT 400 WORDS)

Regulation of protein turnover versus growth state. Studies on the mechanism(s) of initiation of acidic vacuolar proteolysis in cells of stationary ascites hepatoma

1. After transplantation, the rat AH-130 Yoshida ascites hepatoma enters a phase of exponential (log) growth, followed by a quasi-stationary (sta) state. Combining measurements made in vivo and in vitro, cessation of protein accumulation (growth) in sta phase has previously been shown to result from convergent reduction of protein synthesis and enhancement of protein breakdown [Tessitore, Bonelli, Cecchini, Amenta & Baccino (1987) Arch. Biochem. Biophys. 255, 372-384]. 2. One day after labelling in the animal with [3H]leucine, AH-130 cells were processed for short-term assays in vitro to measure rates of endogenous protein breakdown. 3. Exposure of AH-130 cells to inhibitors interfering with different steps of the acidic vacuolar pathway (AVP) showed that: (i) in log tumour cells the AVP was extensively suppressed; (ii) in sta tumour cells virtually all of the proteolytic acceleration was accounted for by activation of the AVP. 4. Treating log tumour cells with glucagon, cyclic AMP, or nutritional deprivation failed to elevate substantially the proteolytic rates. Nor could the elevation in proteolysis be explained by changes in free amino acids, which were more concentrated in the ascitic fluid of sta tumours. 5. The enhanced proteolysis in sta tumour cells was not associated with any increase in the intracellular activity levels of lysosomal cathepsins B, D, H, and L. 6. The above growth-related modulation of protein breakdown in AH-130 cells was probably a reflection of the tumour growth state rather than the direct effect of environmental stimuli.

Regression of autophagic vacuoles in pancreatic acinar, seminal vesicle epithelial, and liver parenchymal cells: a comparative morphometric study of the effect of vinblastine and leupeptin followed by cycloheximide treatment

Treatment of mice with both leupeptin (0.06 mg/g body wt) and vinblastine (0.05 mg/g body wt) for 2 h caused a many-fold enlargement of the autophagic-lysosomal compartment of pancreatic acinar, seminal vesicle epithelial, and liver parenchymal cells. In all three types of cells a predominance of large, dense bodies was seen after leupeptin treatment and that of typical autophagic vacuoles were seen after vinblastine treatment. An exponential decrease of the volume fraction of autophagic vacuoles was observed in leupeptin-treated cells after the administration of cycloheximide (0.2 mg/g body wt). The half-life of autophagic vacuoles estimated from the decay curve was 5.3, 5.7, and 6.6 min for pancreatic, seminal vesicle, and liver cells, respectively. Our data suggest that sequestered cytoplasmic material rapidly enters the lysosomes in leupeptin-treated cells and accumulates in this compartment. In contrast, no regression of the autophagic vacuole compartment of pancreatic and seminal vesicle cells was observed after the administration of cycloheximide to animals pretreated with vinblastine, and only a slight decrease was seen in liver cells. These observations show that the lifetime of autophagic vacuoles is prolonged by vinblastine resulting in their accumulation in the cells. However, our measurements also lend support to the view that in addition to the accumulatory effect on undegraded cytoplasmic material, stimulation of sequestration may play a role in the enlargement of the autophagic lysosomal compartment after treatment with leupeptin as well as with vinblastine in all three types of cells investigated.

Morphometric evaluation of the turnover of autophagic vacuoles after treatment with Triton X-100 and vinblastine in murine pancreatic acinar and seminal vesicle epithelial cells

Large numbers of autophagic vacuoles were found in murine pancreatic acinar and seminal vesicle epithelial cells following the administration of Triton X-100 or vinblastine for 4 h. The autophagic vacuoles disappeared rapidly from the cells after the administration of cycloheximide to animals pretreated with Triton X-100. The decay in seminal vesicle cells appeared to follow first-order kinetics with an estimated t1/2 of 8.7 min. The regression in pancreatic cells was equally rapid and less than half the initial volume of autophagic vacuoles was found at the 12th min after cycloheximide injection. This time, the decay curve appeared to be linear rather than exponential. Our data, together with the work of others, support the view that the average half-life of autophagic vacuoles is a fairly constant parameter kept within the range of 6-9 min in various types of mouse and rat cell when the late steps of autophagocytosis (i.e. the fusion of autophagosomes and lysosomes and the degradation within lysosomes) are not affected. The regression of autophagic vacuoles was slow in mice pretreated with vinblastine (t1/2 of about 27-30 min) suggesting that this drug slows down the turnover of autophagic vacuoles. Morphometric evaluation of the regression of the autophagic vacuole compartment after cycloheximide treatment can be used as a tool to distinguish between treatments which elevate the amount of autophagic vacuoles within the cells by increasing the rate of sequestration from those which expand the autophagic vacuole compartment by causing accumulation of autophagic vacuoles as a result of blockade of the late steps of the autophagic process.