Hydrolysis of an exogenous 125I-labelled protein by rat yolk sacs. Evidence for intracellular degradation within lysosomes.

When added to the serum-free medium in which 17.5-day rat yolk sacs were incubated, formaldehyde-denatured 125I-labelled bovine serum albumin was rapidly degraded. More than 80% of the radiolabelled digestion products appearing in the incubation medium consisted of [125I]iodo-L-tyrosine; larger digestion products were found only in association with the yolk-sac tissue. In the early stages of an incubation, low-molecular-weight digestion products began to appear in the incubation medium only after they could be detected within the tissue, and progressive association of trichloroacetic acid-insoluble radioactivity with the tissue preceded both these events. None of the observed proteolysis could be attributed to proteinases released into the incubation medium. Tissue-associated acid-insoluble radioactivity showed a lysosomal distribution on sub-cellular fractionation, and cell-free homogenates of yolk sacs degraded albumin only at acid pH values. Progressively decreasing the rat of pinosome formation (either by progressively lowering the incubation temperature or by the use of increasing concentrations of the metabolic inhibitor rotenone) caused a corresponding decrease in the rate of degradation of albumin. These findings indicate that, in vitro, formaldehyde-denatured 125I-labelled bovine serum albumin is digested by rat yolk sacs exclusively intracellularly, within lysosomes.     

Evidence for a proteolytic modification of liver pyruvate kinase in fasted rats.

Liver pyruvate kinase was purified to homogeneity from rats fed a high carbohydrate, low protein diet (LPK-C) and from rats fasted for 84 h (LPK-F). Although the enzymes have similar electrophoretic mobilities in 7% polyacrylamide disc gels, the specific activity of LPK-C was two to three times the value of the specific activity of LPK-F. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of LPK-C yields a single protein band of 56,000 daltons. In contrast, LPK-F yields two bands of protein. Approximately one-third of the LPK-F has an electrophoretic mobility similar to the 56,000-dalton LPK-C peptide. The remaining two-thirds of the LPK-F protein migrates as a 51,000-dalton peptide. Cyanogen bromide was used to cleave LPK-C and LPK-F. Similar peptide patterns were obtained from LPK-C and LPK-F when the cyanogen bromide fragments were resolved by 12% polyacrylamide gel electrophoresis in 7.5 m urea containing 6 mm Triton X-100 and 5% acetic acid. Separation of the two peptides from LPK-F was accomplished by selective immunologie absorption of the 56,000-dalton peptide with anti-LPK-C gammaglobulin immobilized on Sepharose 4B. Tryptic digests of LPK-C, LPK-F and the 51,000-dalton peptide yield similar peptide patterns when analyzed via sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis. These results suggest that the 51,000-dalton peptide could be derived by a proteolytic cleavage or limited digestion of the 56,000-dalton subunit. Phosphorylation of LPK-C and LPK-F by [γ-³²P]ATP in vitro with cyclic AMP-activated protein kinase results in covalent incorporation of ${}^{32}$P into only the 56,000-dalton subunit. These results suggest that anin vivo proteolytic modification that yields the 51,000-dalton subunit.     

Cardiolipin degradation by rat liver lysosomes.

The lysosomal subcellular fraction of rat liver contains acid hydrolases which can carry out the degradation of cardiolipin to yield water-soluble products and free fatty acids. The time course of appearance of the products indicates that the major catabolic route involves the sequential removal of three of the fatty acids, followed by hydrolysis to acylglycerophosphoryl glycerol (from which the fatty acid is subsequently removed) and d-glycerophosphate (which is hydrolysed to give free phosphate and glycerol). The phospholipase A activity responsible for removal of the first fatty acid is located in the lysosomal fraction.     

Inhibition of intracellular protein degradation by ethanol in perfused rat liver.

Ethanol (50 mM) inhibited proteolysis in the perfused rat liver during stringent amino acid deprivation and also in the presence of normal and 10 times normal concentrations of plasma amino acids. The concentration-response curve of ethanol reached a plateau after 5 mM in both the presence and the absence of normal plasma amino acids, suggesting inhibition by oxidation products of ethanol. Intracellular glutamine, tyrosine and proline increased in concentration with ethanol, but the increases were too small to explain the observed inhibition of proteolysis. The uptake of 125I-asialofetuin was slightly decreased and the output of ammonia increased in the presence of ethanol. These, together with a significant suppression of basal proteolysis in the presence of amino acids, suggest that lysosomal function was directly affected. Electron-microscopic examination of lysosomal components showed that the aggregate volume of autophagosomes (initial vacuoles) were significantly smaller in livers perfused with ethanol than in controls. However, the equivalent volume of autolysosomes (degradative vacuoles) was the same in both groups. According to these results, ethanol inhibits protein degradation in the liver by two discrete mechanisms: one decreasing the formation of autophagic vacuoles and the other involving lysosomotropic inhibition, possibly via ammonia.     

Modifications of liver lysosomes in diabetic rats.

Recently investigators reported ultrastructural modifications of rat liver lysosomes which probably correlate with an increased level of blood plasma glucagon in streptozotocin-diabetes. We are investigating whether biochemical changes occur in this condition. Lysosome fragility is increased in the hepatocytes of streptozotocin-diabetic rats. Moreover the plasma activity of two glycosidases, B-N-acetylglucosaminidase and B-galactosidase, is markedly increased in streptozotocin-treated rats. Both these changes are largely prevented by insulin treatment. These findings support the idea that the morphologic and biochemical modifications of the hepatocytes, which are observed in experimental diabetes, involve the lysosomes showing an increased autophagic activity which is probably connected with enhanced liver protein catabolism.     

Swainsonine inhibits glycoprotein degradation by isolated rat liver lysosomes

Rat liver lysosomes, isolated from metrizamide gradients by the method of Wattiaux et al. (Wattiaux, R., Wattiaux-de Coninck, S., Ronveaux-Dupol, M.F., and Dubois, F. (1978) J. Cell Biol. 78, 349-368) took up from the medium and degraded several marker protein preparations, viz. 125I-asialofetuin, [35S]methionine-labeled hemoglobin, and [3H]leucine-labeled rat liver cytosol proteins. Rates were indistinguishable for all the markers, indicating that uptake was by a nonspecific process analogous to fluid pinocytosis. No effect of added MgATP or K+ was observed. Lysosomal degradation of all the markers was inhibited by 10(-4) M chloroquine. Swainsonine, on the other hand, at 10(-5) M, inhibited the breakdown only of the glycoprotein, 125I-asialofetuin. In the presence of the inhibitors, there was an accumulation of markers in the lysosomes in amount corresponding to the decreased breakdown, indicating that uptake was unaffected. Degradation and inhibition were measured at pH 7.0, 6.0, and 5.0 with both intact lysosomes and with lysosomes disrupted by the addition of 0.2% Triton X-100. Degradation with intact lysosomes was relatively independent of pH. On the other hand, activity with disrupted lysosomes was negligible at pH 7.0 and rose rapidly with decreasing pH. Inhibition by 10(-4) M chloroquine and 10(-5) M swainsonine with intact lysosomes decreased sharply with decreasing pH and did not occur with disrupted lysosomes.     

Effects of insulin on cardiac lysosomes and protein degradation

Hearts perfused in the absence of added insulin had 1) accelerated rates of protein degradation, as assessed by release of phenylalanine and tyrosine; 2) increased rates of release of seven other amino acids; 3) decreased lysosomal latency and sedimentable lysosomal enzyme activity; 4) increased numbers of autophagic vacuoles in cardiac muscle cells; and 5) decreased activity of beta-N-acetylglucosaminidase in dense lysosomes (1.06-1.09 g/ml), as compared to hearts perfused in the presence of the hormone. After 3 h of perfusion in the absence of insulin, the changes that developed in protein degradation, lysosomal latency, and sedimentability, and in enzyme activity in dense lysosomes, were reversed by insulin addition during 90 min of subsequent perfusion. These studies suggest a role for insulin in controlling the activity of the lysosomal system and the involvement of this system in protein degradation, particularly in insulin-deprived tissue.     

Physiological role of peroxisomal beta-oxidation in liver of fasted rats

In the livers of fasted rats, the activity of peroxisomal palmitocyl-CoA oxidation (NADH production) was increased more rapidly and markedly than that of mitochondrial carnitine palmitoyltransferase, which is the rate limiting enzyme of mitochondrial beta-oxidation. The peroxisomal oxidizing activity was about twice that of the control throughout the period of fasting (1-7 days). carnitine acetyltransferase activity was increased to a similar extent in both peroxisomes and mitochondria. A possible physiological role of liver peroxisomes may thus be as an effective supply of NADH2, acetyl residues and short and medium-length fatty acyl-CoA in the cells on the enhancement of peroxisomal beta-oxidation of the animals under starvation; these substances thus produced may be transported into the mitochondria as energy sources.     

Immunocytochemical localization of hepatic fatty acid binding protein in the liver of fed and fasted rats

Summary The immunocytochemical localization of fatty acid binding protein (FABP) of liver type was studied at light and electron microscopic levels by the peroxidase-antiperoxidase (PAP) method using a specific polyclonal antibody against FABP in the liver of fed and fasted rats. In the liver of rats fed ad libitum, the intense immunoreactivity was confined to portions of the liver cell cytoplasm adjacent to the glycogen area. After 2-days' fasting, such a focal intracellular localization of the immunoreactivity was abolished, in association with the disappearance of the glycogen area, and was replaced by a diffuse distribution of the immunoreactivity throughout the cytoplasm, with higher intensity at the periphery of the cells. In liver cells exhibiting an overall hypertrophy of smooth endoplasmic reticulum (SER) induced by the treatment of fasted rats with phenobarbital, the peripheral localization of FABP immunoreactivity ramained unchanged compared with that obtained in the case of fasting alone, and the immunoreactivity did not occur in association with the proliferated SER in the central cytoplasm. These results suggest that FABP, although cytosolic in nature, changes its localization within the liver cells in response to the general metabolic alterations caused by the starvation, inferring that FABP is intimately involved in the intracellular transport and metabolism of free fatty acids.     

Immunocytochemical localization of hepatic fatty acid binding protein in the liver of fed and fasted rats

The immunocytochemical localization of fatty acid binding protein (FABP) of liver type was studied at light and electron microscopic levels by the peroxidase-antiperoxidase (PAP) method using a specific polyclonal antibody against FABP in the liver of fed and fasted rats. In the liver of rats fed ad libitum, the intense immunoreactivity was confined to portions of the liver cell cytoplasm adjacent to the glycogen area. After 2-days' fasting, such a focal intracellular localization of the immunoreactivity was abolished, in association with the disappearance of the glycogen area, and was replaced by a diffuse distribution of the immunoreactivity throughout the cytoplasm, with higher intensity at the periphery of the cells. In liver cells exhibiting an overall hypertrophy of smooth endoplasmic reticulum (SER) induced by the treatment of fasted rats with phenobarbital, the peripheral localization of FABP immunoreactivity remained unchanged compared with that obtained in the case of fasting alone, and the immunoreactivity did not occur in association with the proliferated SER in the central cytoplasm. These results suggest that FABP, although cytosolic in nature, changes its localization within the liver cells in response to the general metabolic alterations caused by the starvation, inferring that FABP is intimately involved in the intracellular transport and metabolism of free fatty acids.