Inhibition of autophagic-lysosomal delivery and autophagic lactolysis by asparagine

Overall autophagy was measured in isolated hepatocytes as the sequestration and lysosomal hydrolysis of electroinjected [14C]lactose, using HPLC to separate the degradation product [14C]glucose from undegraded lactose. In addition, the sequestration step was measured separately as the transfer from cytosol to sedimentable cell structures of electroinjected [3H]raffinose or endogenous lactate dehydrogenase (LDH; in the presence of leupeptin to inhibit lysosomal proteolysis). Inhibitor effects at postsequestrational steps could be detected as the accumulation of autophaged lactose (which otherwise is degraded intralysosomally), or of LDH in the absence of leupeptin. Asparagine, previously shown to inhibit autophagic but not endocytic protein breakdown, strongly suppressed the autophagic hydrolysis of electroinjected lactose. Vinblastine, which inhibits both types of degradation, likewise suppressed lactose hydrolysis. Asparagine had little or no effect on sequestration, but caused an accumulation of autophaged LDH and lactose, indicating inhibition at a postsequestrational step. Neither asparagine nor vinblastine affected the degradation of intralysosomal lactose preaccumulated in the presence of the reversible lysosome inhibitor propylamine. However, if lactose was preaccumulated in the presence of asparagine, both asparagine and vinblastine suppressed its subsequent degradation. The data thus indicate that autophagic-lysosomal delivery, i.e., the transfer of autophaged material from prelysosomal vacuoles to lysosomes, is inhibited selectively by asparagine and non-selectively by vinblastine.     

Temperature dependence of protein degradation, autophagic sequestration and mitochondrial sugar uptake in rat hepatocytes

Lysosomal (propylamine-sensitive) protein degradation as well as the energy-dependent (chymostatin-sensitive) part of the non-lysosomal protein degradation was found to be strongly affected by temperature in isolated rat hepatocytes, the activation energy (Ea) being about 25 kcal/mol for both processes. In contrast, the energy-independent (chymostatin-resistant) part of the non-lysosomal degradation had an Ea of approx. 10 kcal/mol only. Sequestration of electroinjected [14C]sucrose into sedimentable organelles showed a pronounced temperature dependence. By means of digitonin extraction it was possible to distinguish between a moderately temperature-sensitive mitochondrial sugar uptake (Ea approx. 12 kcal/mol) and a strongly temperature-dependent autophagic sequestration (Ea approx. 22 kcal/mol). There was no significant autophagic sequestration below 20 degrees C. The sequestration process is more temperature-sensitive than, for example, the early steps of endocytosis, and is likely to represent the major controlling step in the overall autophagic-lysosomal pathway.     

Use of digitonin extraction to distinguish between autophagic-lysosomal sequestration and mitochondrial uptake of [14C]sucrose in hepatocytes.

In isolated rat hepatocytes, electroinjected [14C]sucrose is sequestered both by mitochondria and by autophagosomes/lysosomes. Radioactivity can be selectively extracted from the latter organelles by low concentrations of digitonin, thereby providing a specific bioassay for autophagic sequestration. By including a digitonin extraction step in the assay procedure, autophagic [14C]sucrose sequestration could be shown to be virtually completely (greater than 90%) suppressed by the autophagy inhibitor 3-methyladenine (10 mM), whereas mitochondrial sugar uptake was unaffected. An amino acid mixture likewise suppressed autophagic sequestration very strongly, while having no detectable effect on the mitochondria.     

Use of a hydrolysable probe, [14C]lactose, to distinguish between pre-lysosomal and lysosomal steps in the autophagic pathway

[14C]Lactose, introduced into the cytosol of isolated rat hepatocytes by means of electropermeabilization, is sequestered autophagically in the same way as the established sequestration probe, [14C]sucrose. However, unlike the inert sucrose molecule, lactose is rapidly hydrolysed in the lysosomes, and can therefore be used to probe the last step of the autophagic pathway (i.e. fusion with the lysosome). During autophagy lactose is present only at a low, steady-state level in pre-lysosomal vacuoles (probably autophagosomes), serving as a useful marker for these organelles. If autophagosome-lysosome fusion is blocked with vinblastine (Kovács et al., Exp cell res 137 (1982) 191), [14C]lactose will accumulate continuously as a function of the sequestration rate, and reach a high level in the pre-lysosomal vacuoles. Density gradient analysis, using chloroquine (CLQ) to alter lysosomal density, suggests that these organelles have a broad density distribution (1.08-1.13 g/ml), thus differing significantly from the distribution of lysosomes.     

Amino acid control of autophagic sequestration and protein degradation in isolated rat hepatocytes

Sequestration of the inert cytosolic marker [14C]sucrose by sedimentable organelles was measured in isolated rat hepatocytes made transiently permeable to sucrose by means of electropermeabilization. Lysosomal integrity, protein degradation, autophagic sequestration, and other cellular functions were not significantly impaired by the electric treatment. Hepatocytes sequestered sucrose at an initial rate of approximately 10%/h, which is threefold higher than the estimated rate of autophagic-lysosomal protein degradation. Almost one-third would appear to represent mitochondrial fluid uptake; the rest was nearly completely and specifically inhibited by 3-methyladenine (3MA) and can be regarded as autophagic sequestration. A complete amino acid mixture was somewhat less inhibitory than 3MA, and partially antagonized the effect of the latter. This paradoxical effect, taken together with the high sequestration rate, may suggest heterogeneity as well as selectivity in autophagic sequestration. There was no detectable recycling of sequestered [14C]sucrose between organelles and cytosol. Studies of individual amino acids revealed histidine as the most effective sequestration inhibitor. Leucine may have a regulatory function, as indicated by its unique additive/synergistic effect, and a combination of Leu + His was as effective as the complete amino acid mixture. Asparagine inhibited sequestration only 20%, i.e., its very strong effect on overall (long-lived) protein degradation must partially be due to post-sequestrational inhibition. The lysosomal (amine-sensitive) degradation of short-lived protein was incompletely inhibited by 3MA, indicating a contribution from nonautophagic processes like crinophagy and endocytic membrane influx. The ability of an amino acid mixture to specifically antagonize the inhibition of short-lived protein degradation by AsN + GIN (but not by 3MA) may suggest complex amino acid interactions at the level of fusion between lysosomes and other vesicles in addition to the equally complex interactions at the level of autophagic sequestration.     

Energy dependence of autophagic protein degradation in isolated rat hepatocytes

The effect of small changes in intracellular ATP on autophagic flux was studied in isolated rat hepatocytes by using inhibitors of ATP production or by varying the metabolic conditions. The following observations were made. There was a linear relationship between endogenous protein degradation and intracellular ATP, the rate of proteolysis declining with decreasing ATP concentrations. 15% of the maximal proteolysis is either independent of ATP or has a very high affinity for this metabolite. There was a linear relationship between the autophagic sequestration of cytosolic [14C]sucrose and intracellular ATP, the sequestration rate decreasing with decreasing ATP concentrations. ATP depletion did not cause release of [14C]sucrose previously sequestered in autophagosomes and lysosomes at high ATP levels. Intracellular accumulation of chloroquine, used as an indicator of the pH inside lysosomes and other acidic cell compartments, diminished with decreasing cellular ATP content. Amino acids inhibited proteolysis without affecting ATP levels or chloroquine accumulation. We conclude from the high sensitivity of autophagy towards relatively small changes in the concentration of intracellular ATP that, besides amino acids, ATP is a very important factor in controlling the rate of autophagy in rat hepatocytes.     

Specific inhibition by NH4Cl of autophagy-associated proteolysis in cultured fibroblasts

Rat embryo fibroblasts, prelabeled with [¹⁴C]leucine, showed an enhanced degradation of cell protein as well as increased peptide release when placed in a serum-deficient medium. NH₄Cl inhibited only the induced proteolysis, but had no effect on basal protein turnover. Electron microscopy studies showed that enhanced proteolysis was associated with an increase in autophagic vacuoles containing amorphous and membranous debris, and that NH₄Cl markedly increased the number of these intracellular vacuoles. Upon release from NH₄Cl inhibition, these cells showed a compensatory enhanced release of ¹⁴C into the medium and a decrease in the number of intracellular degradative vacuoles. We conclude that enhanced proteolysis reflects an activation of the autophagic-lysosomal system in these cells and that NH₄Cl inhibits the final hydrolysis and release steps in this mechanism.     

Amino acid inhibition of the autophagic/lysosomal pathway of protein degradation in isolated rat hepatocytes

Protein degradation in isolated rat hepatocytes, as measured by the release of [¹⁴C]valine from pre-labelled protein, is partly inhibited by a physiologically balanced mixture of amino acids. The inhibition is largely due to the seven amino acids leucine, phenylalanine, tyrosine, tryptophan, histidine, asparagine and glutamine.When the amino acids are tested individually at different concentrations, asparagine and glutamine are the strongest inhibitors. However, when various combinations are tested, a mixture of the first five amino acids as well as a combination of leucine and asparagine inhibit protein degradation particularly strongly.The inhibition brought about by asparagine plus leucine is not additive to the inhibition by propylamine, a lysosomotropic inhibitor; thus indicating that the amino acids act exclusively upon the lysosomal pathway of protein degradation.Following a lag of about 15 min the effect of asparagine plus leucine is maximal and equal to the effect of propylamine, suggesting that their inhibition of the lysosomal pathway is complete as well as specific.Degradation of endocytosed ¹²⁵I-labelled asialofetuin is not affected by asparagine plus leucine, indicating that the amino acids do not affect lysosomes directly, but rather inhibit autophagy at a step prior to the fusion of autophagic vacuoles with lysosomes.The aminotransferase inhibitor, aminooxyacetate, does not prevent the inhibitory effect of any of the amino acids, i.e. amino acid metabolites are apparently not involved.     

Paradoxical stimulation by amino acids of the degradation of [35S]methionine-labelled, short-lived protein in isolated rat hepatocytes

A complete amino acid mixture inhibited the degradation of long-lived and [14C]valine-labelled short-lived protein in isolated rat hepatocytes, but paradoxically stimulated the degradation of [35S]methionine-labelled short-lived protein. The stimulation persisted in the presence of autophagiclysosomal pathway inhibitors like 3-methyladenine and propylamine, indicating the existence of an hitherto unrecognized non-lysosomal degradation mechanism with selectivity towards methionine-rich proteins or peptide regions.     

Studies of the beta-galactoside transporter in inverted membrane vesicles of Escherichia coli. I. Symmetrical facilitated diffusion and proton gradient-coupled transport.

Facilitated diffusion of [14C]lactose into inverted membrane vesicles of Escherichia coli was measured using HgCl2 as a stopping reagent and polylysine to flocculate the vesicles for filtration. Equilibration of lactose between the internal and external volumes required expression of the y gene of the lac operon and was inhibited by thiodigalactoside or by prior incubation with N-ethylmaleimde or HgCl2. The initial rate of uptake was saturable, with a Kt of 0.95 mM. Counterflow of [14C]lactose was demonstrated in either direction. ATP hydrolysis or respiration drove the efflux of internal lactose. The effect of ATP required addition of F1 coupling factor (ATPase) from E. coli when lactose transport was studied in F1-deficient inverted vesicles. Accumulation of lactose against a concentration gradient was achieved by forming an artificial electrochemical proton gradient consisting of a membrane potential negative inside or a pH gradient basic inside. Addition of ATP inhibited this proton driven uptake showing that it occurred in inverted vesicles. It was concluded that the lactose-proton co-transport protein (M protein) is qualitatively symmetrical with respect to the facilitated diffusion of lactose and the coupling of proton and lactose transport.     

Intracellular protein degradation and autophagy in isolated pancreatic acini of the rat

Simultaneous investigation of protein degradation and autophagy of isolated exocrine pancreatic cells is carried out here for the first time in a systematic way by a complex biochemical, morphological and morphometrical approach. Protein degradation proceeds with a decreasing rate of 4-1.5 per cent per h over a 4-h period indicating a comparatively low degradation capacity. Cells in freshly isolated acini do not contain autophagic vacuoles but the latter appear within an hour in vitro and their quantity remains close to a steady state during the subsequent 3 h. Both traditional inhibitors of the autophagic-lysosomal pathway, e.g. vinblastine, leupeptin, and lysosomotropic amines together with the recently introduced 3-methyladenine, inhibit degradation to a similar maximal extent, offering the possibility of the estimation of the ratio of lysosomal/non-lysosomal degradation. In pancreatic acinar cells autophagic sequestration is unaffected and protein degradation is inhibited inside secondary lysosomes by leupeptin and lysosomotropic amines, while 3-methyladenine prevents the formation of autophagosomes. Vinblastine seems to act by inhibiting the fusion of autophagosomes with lysosomes and there is no evidence for the stimulation of autophagic sequestration by vinblastine in the present system. The effect of inhibitors of protein breakdown on protein synthesis is variable and does not correlate with their influence on degradation. Amino acids strongly stimulate protein synthesis, but in contrast to what is found in liver cells, they do not seem to affect protein degradation or autophagy significantly, thus indicating major regulatory differences of these processes between pancreatic acinar cells and hepatocytes.     

Therapeutic effects of remediating autophagy failure in a mouse model of Alzheimer disease by enhancing lysosomal proteolysis

The extensive autophagic-lysosomal pathology in Alzheimer disease (AD) brain has revealed a major defect: in the proteolytic clearance of autophagy substrates. Autophagy failure contributes on several levels to AD pathogenesis and has become an important therapeutic target for AD and other neurodegenerative diseases. We recently observed broad therapeutic effects of stimulating autophagic-lysosomal proteolysis in the TgCRND8 mouse model of AD that exhibits defective proteolytic clearance of autophagic substrates, robust intralysosomal amyloid-β peptide (Aβ) accumulation, extracellular β-amyloid deposition and cognitive deficits. By genetically deleting the lysosomal cysteine protease inhibitor, cystatin B (CstB), to selectively restore depressed cathepsin activities, we substantially cleared Aβ, ubiquitinated proteins and other autophagic substrates from autolysosomes/lysosomes and rescued autophagic-lysosomal pathology, as well as reduced total Aβ40/42 levels and extracellular amyloid deposition, highlighting the underappreciated importance of the lysosomal system for Aβ clearance. Most importantly, lysosomal remediation prevented the marked learning and memory deficits in TgCRND8 mice. Our findings underscore the pathogenic significance of autophagic-lysosomal dysfunction in AD and demonstrate the value of reversing this dysfunction as an innovative therapeautic strategy for AD.     

Therapeutic effects of remediating autophagy failure in a mouse model of Alzheimer disease by enhancing lysosomal proteolysis

The extensive autophagic-lysosomal pathology in Alzheimer disease (AD) brain has revealed a major defect

in the proteolytic clearance of autophagy substrates. Autophagy failure contributes on several levels to AD pathogenesis and has become an important therapeutic target for AD and other neurodegenerative diseases. We recently observed broad therapeutic effects of stimulating autophagic-lysosomal proteolysis in the TgCRND8 mouse model of AD that exhibits defective proteolytic clearance of autophagic substrates, robust intralysosomal amyloid-β peptide (Aβ) accumulation, extracellular β-amyloid deposition and cognitive deficits. By genetically deleting the lysosomal cysteine protease inhibitor, cystatin B (CstB), to selectively restore depressed cathepsin activities, we substantially cleared Aβ, ubiquitinated proteins and other autophagic substrates from autolysosomes/lysosomes and rescued autophagic-lysosomal pathology, as well as reduced total Aβ40/42 levels and extracellular amyloid deposition, highlighting the underappreciated importance of the lysosomal system for Aβ clearance. Most importantly, lysosomal remediation prevented the marked learning and memory deficits in TgCRND8 mice. Our findings underscore the pathogenic significance of autophagic-lysosomal dysfunction in AD and demonstrate the value of reversing this dysfunction as an innovative therapeautic strategy for AD.     

Combined glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase in catecholamine-stimulated guinea-pig cardiac muscle. Comparison with mass-action ratio of creatine kinase.

The steady-state reactant levels of triose-phosphate isomerase and the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system were examined in guinea-pig cardiac muscle. Key glycolytic intermediates, including glyceraldehyde 3-phosphate were directly measured and compared with those of creatine kinase. Non-working Langendorff hearts as well as isolated working hearts were perfused with 5 mM glucose (plus insulin) under normoxia conditions to maintain lactate dehydrogenase near-equilibrium. The cytosolic phosphorylation potential ([ATP]/([ADP].[Pi])) was derived from creatine kinase and the free [NAD+]/([NADH].[H+]) ratio from lactate dehydrogenase. In Langendorff hearts glycolysis was varied from near-zero flux (hyperkalemic cardiac arrest) to higher than normal flux (normal and maximum catecholamine stimulation). The triose-phosphate isomerase was near-equilibrium only in control or potassium-arrested Langendorff hearts as well as in postischemic 'stunned' hearts. However, when glycolytic flux increased due to norepinephrine or due to physiological pressure-volume work the enzyme was displaced from equilibrium. The alternative phosphorylation ratio [ATP]'/([ADP]).[Pi]) was derived from the magnesium-dependent glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system assigning free magnesium different values in the physiological range (0.1-2.0 mM). As predicted, [ATP]/([ADP].[Pi]) and [ATP]'/([ADP]'.[Pi]') were in excellent agreement when glycolysis was virtually halted by hyperkalemic arrest (flux approximately 0.2 mumol C3.min-1.g dry mass-1). However, the equality between the two phosphorylation ratios was not abolished upon resumption of spontaneous beating and also not during adrenergic stimulation (flux approximately 5-14 mumol C3.min-1.g dry mass-1). In contrast, when flux increased due to transition from no-work to physiological pressure-volume work (rate increase from approximately 3 to 11 mumol C3.min-1.g dry mass-1), the two ratios were markedly different indicating disequilibrium of the glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase. Only during adrenergic stimulation or postischemic myocardial 'stunning', not due to hydraulic work load per se, glyceraldehyde-3-phosphate levels increased from about 4 microM to greater than or equal to 16 microM. Thus the guinea-pig cardiac glyceraldehyde-3-phosphate dehydrogenase/phosphoglycerate kinase system can realize the potential for near-equilibrium catalysis at significant flux provided glyceraldehyde-3-phosphate levels rise, e.g., due to 'stunning' or adrenergic hormones.     

Properties of the lactose transport system in Klebsiella sp. strain CT-1.

Highly purified [D-glucose-1-14C]lactose has been used to study the transport of lactose by Klebsiella sp. strain CT-1. Strain CT-1 transports lactose by a lactose-inducible system that exhibited an apparent Km of 6 mM lactose and an apparent Vmax of 140 nmol/min per mg of cell protein. Lactose uptake was inhibited competitively by o-nitrophenyl-beta-D-galactoside with a Ki value of 8 mM, but was not inhibited by thio-beta-methyl-galactoside. D-Glucose, D-mannose, 2-deoxyglucose, and alpha-methyl-D-glucoside also inhibited lactose uptake. Phosphoenolpyruvate-dependent hydrolysis of o-nitrophenyl-beta-D-galactoside and lactose-dependent release of pyruvate from phosphoenolpyruvate by benzene-treated CT-1 cells showed that CT-1 transports lactose by a phosphoenolpyruvate:sugar phosphotransferase system. Correlations between the growth rate of CT-1 on lactose and properties of the transport system indicated that transport is the rate limiting step in utilization of lactose.     

ATP stimulates the hydrolysis of phosphatidylethanolamine in NIH 3T3 cells. Potentiating effects of guanosine triphosphates and sphingosine

Recently, phospholipase D-mediated hydrolysis of phosphatidylethanolamine (PtdEtn) was shown to be stimulated by activators of protein kinase C (Kiss, Z., and Anderson, W. B. (1989) J. Biol. Chem. 264, 1483-1487), suggesting that PtdEtn metabolism may play a role in signal transduction. Here we have studied the possible regulation of PtdEtn hydrolysis by adenine and guanine nucleotides, as well as by sphingosine, both in membranes isolated from [14C]ethanolamine- or [32P]PtdEtn-prelabeled NIH 3T3 cells and in intact cells. In isolated membranes both ATP and ADP stimulated the hydrolysis of PtdEtn. Both nucleotides had maximal (approximately 2-fold) effects at about 0.5 mM concentration. The main water-soluble product of [14C]PtdEtn hydrolysis was [14C]ethanolamine, while in [32P] PtdEtn-prelabeled membranes the nucleotides stimulated the formation of [32P]phosphatidic acid, suggesting the involvement of a phospholipase D-type enzyme. The hydrolysis-resistant analogs of GTP, such as guanosine 5'-3-O-(thio)triphosphate and guanyl-5'-yl imidodiphosphate, greatly potentiated the stimulatory effects of ATP and ADP on PtdEtn hydrolysis. On the other hand, the nonphosphorylating analogs of ATP, adenyl-5'-yl beta,gamma-imidodiphosphate and beta,gamma-methyl-eneadenosine 5'-triphosphate, failed to stimulate PtdEtn hydrolysis both in the absence and presence of guanosine triphosphates. Sphingosine, while exhibiting no effect alone, had a relatively modest (1.2-1.3-fold) potentiating effect on ATP-stimulated PtdEtn hydrolysis in isolated membranes. The effect of sphingosine was mimicked by threo- and erythrosphinganines, while N-acetylsphingosine was without effect. In studies with [14C]ethanolamine-prelabeled intact NIH 3T3 cells, externally added ATP did not stimulate PtdEtn hydrolysis. In contrast, sphingosine and sphinganines had much greater stimulatory effects on PtdEtn hydrolysis in intact cells than with isolated membranes. These data indicate that PtdEtn hydrolysis may be regulated by adenine and guanine nucleotides in addition to, or in cooperation with, the activators of protein kinase C, and that sphingosine may be an additional regulator of PtdEtn hydrolysis.     

Vanadate inhibits the ATP-dependent degradation of proteins in reticulocytes without affecting ubiquitin conjugation

Reticulocytes contain a nonlysosomal, ATP-dependent system for degrading abnormal proteins and normal proteins during cell maturation. Vanadate, which inhibits several ATPases including the ATP-dependent proteases in Escherichia coli and liver mitochondria, also markedly reduced the ATP-dependent degradation of proteins in reticulocyte extracts. At low concentrations (K1 = 50 microM), vanadate inhibited the ATP-dependent hydrolysis of [3H]methylcasein and denatured 125I-labeled bovine serum albumin, but it did not reduce the low amount of proteolysis seen in the absence of ATP. This inhibition by vanadate was rapid in onset, reversed by dialysis, and was not mimicked by molybdate. Vanadate inhibits proteolysis at an ATP-stimulated step which is independent of the ATP requirement for ubiquitin conjugation to protein substrates. When the amino groups on casein and bovine serum albumin were covalently modified so as to prevent their conjugation to ubiquitin, the derivatized proteins were still degraded by an ATP-stimulated process that was inhibited by vanadate. In addition, vanadate did not reduce the ATP-dependent conjugation of 125I-ubiquitin to endogenous reticulocyte proteins, although it markedly inhibited their degradation. In intact reticulocytes vanadate also inhibited the degradation of endogenous proteins and of abnormal proteins containing amino acid analogs. This effect was rapid and reversible; however, vanadate also reduced protein synthesis and eventually lowered ATP levels in the intact cells. Vanadate (10 mM) has also been reported to decrease intralysosomal proteolysis in hepatocytes. However, in liver extracts this effect on lysosomal proteases required high concentrations of vanadate (K1 = 500 microM) and was also observed with molybdate, unlike the inhibition of ATP-dependent proteolysis in reticulocytes.     

Rat lung glucose metabolism after 24 h of exposure to 100% oxygen

Previous studies with lung homogenates and isolated cells have suggested oxygen cell injury results from the inhibition of key enzymes involved in both cytosolic and mitochondrial energy generation. In this study, the extent and pattern of metabolism of D-[U-14C, 5-3H]glucose was examined in perfused lungs isolated from rats before and after 24 h of in vivo exposure to 100% O2. Lung ATP levels after O2 exposure were maintained by a 53% increase in glucose utilization from an unexposed control value of 18.0 +/- 3.2 to 27.5 +/- 3.0 mumol 3H2O.h-1.g dry wt-1, accounted for by an enhanced rate of lactate plus pyruvate production from 15.7 +/- 2.0 to 32.7 +/- 4.1 mumol.h-1.g dry wt-1 with no alteration in lactate-to-pyruvate ratio. CO2 production was unaltered from a control rate of 27.5 +/- 4.0 14CO2 mumol.h-1.g dry wt-1. Maximal rates of glucose metabolism were determined by perfusion with 0.8 mM dinitrophenol, giving for air-exposed lungs a rate of 53.5 +/- 5.0 mumol 3H2O.h-1.g dry wt-1 and increased lactate plus pyruvate and 14CO2 production rates of 46.5 +/- 6.5 and 128.3 +/- 19.6 mumol.h-1.g dry wt-1, respectively. Although this maximal rate of glucose utilization was unaltered in oxygen-exposed lungs, lactate plus pyruvate production was further increased to 80.0 +/- 9.1 mumol.h-1.g dry wt-1 with a concomitant decrease in the dinitrophenol-induced rate of 14CO2 production to 81.5 +/- 9.2 mumol.h-1.g dry wt-1.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the intramitochondrial adenine nucleotides as intermediates in the uncoupler-induced hydrolysis of extramitochondrial ATP.

1. A formula is given that describes the appearance of [14C]ATPADP outside the mitochondria after the addition of [14C] 1atp during the steady-state uncoupler-induced hydrolysis of extramitochondrial ATP. If the transported adenine nucleotides equilibrate with the intramitochondrial pool, [14C]ADP0 would be expected to appear with a lag phase that corresponds with the time needed for the radioactive labelling of the intramitochondrial adenine nucleotide pool. 2. The rates of formation of [14C]ADP outside the mitochondria after addition of [14C]ATP during the steady-state uncoupler-induced ATP hydrolysis catalysed by rat-liver mitochondria at 0 degree C were measured. 3. In the presence of carbonyl cyanide m-chlorophenylhydrazone the time course of the [14]ADPo formation was the same as that predicted on the basis of the above assumption. 4. In the presence of the less effective uncoupler, 2,4-dinitrophenol, the time course of [14C]ADPo formation was not consistent with the theoretical predictions: no lag phase was present and the measured rate was higher than the maximal calculated rate. These results can be explained by assuming a functional interaction between the adenine nucleotide translocator and the mitochondrial ATPase (F1). 5. It is concluded that under phosphorylating as well as dephosphorylating conditions, the adenine nucleotide translocator and the mitochondrial ATPase can be functionally linked to catalyse phosphorylation or dephosphorylation of extramitochondrial ADP or ATP, without participation of the intramitochondrial adenine nucleotides.     

Uptake and degradation of cytoplasmic RNA by hepatic lysosomes. Quantitative relationship to RNA turnover.

Past evidence has suggested that the lysosomal pathway is an important site of cytoplasmic RNA degradation in the hepatic parenchymal cell (Lardeux, B. R., Heydrick, S. J., and Mortimore, G. E. (1987) J. Biol. Chem. 262, 14507-14519). We now provide additional support for this notion by quantitating degradable RNA in lysosomes and correlating its pool size with hepatic RNA degradation. Rat livers, previously labeled with [6-14C]orotic acid, were perfused with graded levels of amino acids over the full range of induced autophagy; RNA degradation was determined from [14C]cytidine release. Close correspondence between the marker beta-acetylglucosaminidase and the breakdown of RNA to cytidine in subcellular fractions indicated that the lysosome was the main site of catabolism, a conclusion supported by the fact that degradation was enhanced when external pH was lowered from 7 to 6. Although [14C]cytidine was also released in homogenates by the action of natural ribonucleases on cytosolic RNA, this source was eliminated by unlabeled exogenous RNA. The size of the degradable RNA pool in lysosomes, determined from the total release of cytidine in homogenates, correlated directly with rates of hepatic RNA degradation over the full range of basal and induced degradation. A direct correlation was also seen between RNA degradation and cytidine pools within lysosomal particles. Because cytosolic cytidine was not taken up by lysosomes under these conditions, the pool could only have arisen from the breakdown of intralysosomal RNA. As determined by cytidine production, these findings support the view that the lysosomal-vacuolar system is the main, if not sole, site of induced and basal RNA degradation in liver.