Role of lysosomal and cytosolic pH in the regulation of macrophage lysosomal enzyme secretion.

Rapid and parallel secretion of lysosomal beta-N-acetylglucosaminidase and preloaded fluorescein-labelled dextran was initiated in macrophages by agents affecting intracellular pH (methylamine, chlorpromazine, and the ionophores monensin and nigericin). In order to evaluate the relative role of changes in lysosomal and cytosolic pH, these parameters were monitored by using pH-sensitive fluorescent probes [fluorescein-labelled dextran or 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein]. All agents except chlorpromazine caused large increases in lysosomal pH under conditions where they induced secretion. By varying extracellular pH and ion composition, the changes in lysosomal and cytosolic pH could be dissociated. Secretion was then found to be significantly modulated by changes in cytosolic pH, being enhanced by alkalinization and severely inhibited by cytosolic acidification. However, changes in cytosolic pH in the absence of stimulus were unable to initiate secretion. Dissociation of the effects on lysosomal and cytosolic pH was also achieved by combining stimuli with either nigericin or acetate. Further support for a role of intracellular pH in the control of lysosomal enzyme secretion was provided by experiments where bicarbonate was included in the medium. The present study demonstrates that an increase in lysosomal pH is sufficient to initiate lysosomal enzyme secretion in macrophages and provides evidence for a significant regulatory role of cytosolic pH.     

Lysosomal alpha-D-mannosidase of rat liver. Purification and comparison with the golgi and cytosolic alpha-D-mannosidases

Rat liver contains alpha-D-mannosidases in lysosomes, Golgi membranes, and cytosol. The lysosomal enzyme has now been purified approximately 30,000-fold over the crude extract and is free of at least 13 other lysosomal hydrolases. The enzyme has an apparent molecular weight of 335,000 by molecular sieve chromatography and 200,000 by sucrose density centrifugation. It is a glycoprotein, as evidenced by its binding to a concanavalin A affinity column and by a positive periodic acid-Schiff stain. The enzyme has a pH optimum near 4.6. Although it is generally insensitive to a large variety of inorganic salts, chelating agents, and sulfhydryl reagents, prolonged exposure to ethylenediaminetetraacetic acid caused loss of activity, which could be restored by the addition of ZnSO4. Substrate specificity studies were performed on the purified lysosomal alpha-D-mannosidase, as well as on the purified Golgi and cytosolic alpha-D-mannosidases. The three enzymes exhibited only very limited activity on native glycoproteins, but were found to be active on glycopeptides and oligosaccharides, hydrolyzing 1 yields 2 and 1 yields 3 linkages, except that the Golgi enzyme had negligible activity towards the latter linkage. Immunological comparisons by antibody precipitation tests and double-diffusion plates indicated that the three enzymes are not immunologically related. The alpha-D-mannosidase isolated from rat epididymis was found to be immunologically very similar, if not identical, to the lysosomal enzyme isolated from rat liver.     

Increase in enzyme activities of prostaglandin biosynthesis and catabolism by acute ureteral ligation in rat kidney

Acute ureteral obstruction increased cyclooxygenase, thromboxane and prostacyclin synthases and NAD+-linked 15-hydroxyprostaglandin dehydrogenase activities in rat kidney. Significant increase in prostaglandin biosynthetic and catabolic activities may mediate some pathological consequences found in obstructive nephropathy.     

Substrate specificities of a bacterial sialidase and rat liver ganglioside GM3 sialyltransferase

Sialidases cleave off sialic acid residues from the oligosaccharide chain of gangliosides in their catabolic pathway while sialyltransferases transfer sialic acid to the growing oligosaccharide moiety in ganglioside biosynthesis. Ganglioside G_M3 is a common substrate for both types of enzymes, for sialidase acting on ganglioside G_M3 as well as for ganglioside G_D3 synthase. Therefore, it is possible that both enzymes recognize similar structural features of the sialic acid moiety of their common substrate, ganglioside G_M3. Based on this idea we used a variety of G_M3 derivatives as glycolipid substrates for a bacterial sialidase (Clostridium perfringens) and for G_D3 synthase (of rat liver Golgi vesicles). This study revealed that those G_M3 derivatives that were poorly degraded by sialidase also were hardly recognized by sialyltransferase (G_D3 synthase). This may indicate similarities in the substrate binding sites of these enzymes.     

Inhibition of glycoprotein catabolism in vivo and in the perfused rat liver.

Leupeptin is a peptide which inhibits several of the lysosomal proteases. When this compound was added in low concentrations to a perfused liver, the degradation of 125I-asialo-fetuin by the liver was dramatically slowed. When 5 mg leupeptin were added to the perfusate 1 h prior to the radioactive glycoprotein, the liver retained from 70 to 90% or the radioisotope 60 min after infusing 125I-asialo-fetuin. However, untreated livers contained less than 20% of the radioactivity at that time. Subcellular fractionation experiments showed that the radioactivity accumulated in the heavy and light mitochondrial fractions (ML) of the homogenate. At 80 min after the glycoprotein was added, almost 40% of the radioactivity was still located with these fractions. Very similar inhibitory effects were seen upon treating rats intravenously with 5 mg of leupeptin 60 min prior to injection of 125I-labelled asialo-fetuin. A 7 fold increase in liver radioactivity was observed 6 hrs after the glycoprotein had been given to the treated animals. Purified human liver cathepsin B digested fetuin to about 3% of total hydrolysis and the major peptide fragment produced had an SDS-electrophoretic mobility equivalent to that of ovalbumin.     

The substrate specificity of bovine and feline lysosomal alpha-D-mannosidases in relation to alpha-mannosidosis

Lysosomal alpha-mannosidases were partially purified from bovine and feline liver and employed to digest a large number of oligosaccharides with structures corresponding to the oligomannosyl parts of complex, hybrid, and high-mannose glycans. The incubation products were identified by high pressure liquid chromatography with reference compounds of defined structure and by acetolysis. For all classes of substrates, the lysosomal alpha-mannosidases displayed a high degree of in vitro specificity with regard to the hydrolysis of mannose residues. Thus, in each case, 1 or at most 2 residues were always preferentially cleaved so that the degradative process proceeded down a well defined pathway. A comparison of the relative efficiency with which lysosomal alpha-mannosidases catalyzed the hydrolysis of particular oligosaccharides and of the structures of the resulting intermediates with those of the compounds accumulated in alpha-mannosidosis allows conclusions to be drawn regarding the nature of the enzymatic defect. In bovine alpha-mannosidosis, the oligosaccharides are those expected for a partial deficiency of normal lysosomal alpha-mannosidase, so that they correspond to intermediates in the normal catabolic pathway. In feline alpha-mannosidosis, in which the alpha-mannosidase deficiency is more severe than in cattle, the accumulated oligosaccharides primarily represent intact oligomannosyl moieties of N-linked glycans rather than the products of residual alpha-mannosidase activity.     

Effects of swainsonine on rat liver and kidney: biochemical and morphological studies

Among the reported effects of the plant toxin swainsonine in animals are a decreased level of Golgi mannosidase II activity, an increase in lysosomal alpha-D-mannosidase activity, oligosaccharide accumulation, vacuolization of cells, and neurological changes. We now find that, in the rat, the alkaloid rapidly induces vacuolization of both liver and kidney cells, but oligosaccharides accumulate only in the latter. We demonstrate by enzyme- and immunocytochemistry that the induced pleomorphic vacuoles are lysosomal in nature. The vacuoles do not appear to be derived from the Golgi apparatus, which retains its typical ultrastructural appearance, but are formed by autophagy. In swainsonine-fed rats, the lysosomal system is highly developed in hepatocytes, Kupffer cells, and cells of the proximal convoluted tubules. The relation of this hypertrophy of the lysosomal system to the known effects of swainsonine on glycoprotein biosynthesis and on Golgi and lysosomal alpha-mannosidases is not clear. In addition, in liver there occurs a marked increase in mitotic figures in the hepatocytes. This occurred in the absence of both cell death and increased liver size as estimated by gross morphology.     

Marked differences in the swainsonine inhibition of rat liver lysosomal alpha-D-mannosidase, rat liver Golgi mannosidase II, and jack bean alpha-D-mannosidase

Swainsonine, a plant toxin, strongly inhibits certain alpha-D-mannosidases but has no effect on others [D. R. P. Tulsiani, T. M. Harris, and O. Touster (1982) J. Biol. Chem. 257, 7936-7939]. The reversible inhibition of jack bean and lysosomal alpha-D-mannosidases has previously been suggested to be similar in nature but quite complex. Specific differences in the action of swainsonine on these two enzymes and on Golgi mannosidase II are reported. (a) The inhibition of the jack bean mannosidase, but not rat liver lysosomal alpha-D-mannosidase or Golgi mannosidase II, is increased by preincubation with the alkaloid. (b) The inhibition of the jack bean and lysosomal enzymes, but not mannosidase II, is competitive at inhibitor concentrations of less than or equal to 0.5 microM. (c) The inhibition of jack bean alpha-mannosidase is largely irreversible, its very limited reversibility being partially dependent upon the swainsonine concentration used and on the time of preincubation with the inhibitor. On the other hand, the inhibition of lysosomal alpha-mannosidase is largely reversible, as shown by dilution experiments and by the use of [3H]swainsonine. Golgi mannosidase II shows intermediate reversibility, the results indicating two modes of binding; one rapid and irreversible, the other much slower and reversible.     

A di-N-acetylchitobiase activity is involved in the lysosomal catabolism of asparagine-linked glycoproteins in rat liver

A perfused rat liver was used to study the effects of 5-diazo-4-oxo-L-norvaline on lysosomal glycoprotein catabolism. Addition of this compound (1.0 mM) to the perfusate reduced activity of beta-aspartyl-N-acetylglucosylamine amidohydrolase by 99% in 1 h. Treated livers were unable to completely degrade endocytosed N-acetyl[14C]glucosamine-labeled asialo-alpha 1-acid glycoprotein as evidenced by a 50% reduction in radiolabeled serum glycoprotein secretion compared to controls. This decreased degradation was matched by a lysosomal accumulation of glycopeptides with the structure: GlcNAc beta(1-4)GlcNAc-Asn. The result suggested the presence of an unrecognized glycosidase in rat liver lysosomes, since this remnant was extended by one more GlcNAc residue than would have been expected after specific inactivation of the amidohydrolase. Such a novel enzyme would therefore catalyze cleavage of the N-acetylglucosamine residue at the reducing end of alpha 1-acid glycoprotein oligosaccharides only following removal of the linking Asn. The activity was then detected in lysosomal extracts by using intact asialo-biantennary oligosaccharides labeled with [3H] galactose or N-acetyl[14C]glucosamine residues as a substrate. To prevent simultaneous digestion of the material from its nonreducing end, beta-D-galactosidase in the enzyme extract was first inactivated with the irreversible active site-directed inhibitor, beta-D-galactopyranosylmethyl-p-nitrophenyltriazene. The observed di-N-acetylchitobiose cleaving activity worked optimally at pH 3.4 and was uniquely associated with the lysosomal fraction of the liver homogenate. The enzyme also cleaved triantennary chains and di-N-acetylchitobiose, but failed to hydrolyze substrates that had been reduced with NaBH4. The new glycosidase was well separated from N-acetyl-beta-D-glucosaminidase (assayed with p-nitrophenyl-beta-D-glucosaminide) by gel filtration chromatography and had an apparent molecular weight of 37,000. A similar enzyme that hydrolyzes di-N-acetylchitobiose had previously been found in extracts of human liver (Stirling, J. L. (1974) FEBS Lett. 39, 171-175).     

Substrate specificities of cathepsin A,L and A,S from pig kidney

The substrate specificities of two different molecular sizes of cathepsin A, A,L (large form) and A,S (small form), for synthetic substrates were examined kinetically. Both enzymes showed a similar broad substrate specificity against various acyl dipeptides, amino acid esters, and amino acid amides. Z-Phe-Ala and Ac-Phe-OEt were good substrates. Peptides containing hydrophobic amino acids were hydrolyzed rapidly. The presence of hydrophobic amino acid residues, not only at the C-terminal position but also at the second position and probably the third position from the C-terminal, resulted in an increase in the rate of hydrolysis. Peptides containing glycine and proline were hydrolyzed slowly. Inhibition studies with Z-D-Phe-D-Ala and Z-Phe suggested that the peptidase and esterase activities of the enzymes are both catalyzed by the same site of the enzyme molecule, but it remains to be elucidated whether or not the binding sites for peptides and esters are the same.     

Substrate specificities of Cl- -activated arginine aminopeptidases from human and rat origin

The substrate specificities of four Cl^?-activated arginine aminopeptidases purified from the livers and inflammatory exudates of the rat, human fetal livers, and human erythrocytes were studied using peptides and N-l-aminoacyl-2-naphthylamides as substrates. With 2-naphthylamide substrates, these aminopeptidases showed similar substrate specificity; only the derivatives of Arg and Lys were measurably hydrolyzed. Di- and tripeptides with Arg or Lys as the N-terminal residue were readily split by the enzymes from the livers and inflammatory exudates of the rat and human fetal livers but oligopeptides were not hydrolyzed. Arg- and Lys-peptides were also hydrolyzed by the erythrocyte enzyme but this enzyme additionally split several other peptides, oligopeptides being hydrolyzed at internal bonds. The following properties were similar for all four arginine aminopeptidases: Dipeptides were preferred over tripeptides both in substrate binding and catalysis. The rat and human liver, rat exudate, and human erythrocyte enzymes revealed similar K_m values for the best substrates, the values increasing in the following order: ArgPhe, ArgTrp, ArgLys < ArgVal, ArgGly, Arg-2-naphthylamide < ArgGlyGly. The k_cat values were also similar for the four arginine aminopeptidases. Arg-2-naphthylamide was by far the most rapidly hydrolyzed substrate by all enzymes followed by ArgPhe and ArgTrp. With peptide substrates the highest Cl^? activation (10–20%) was found with ArgPhe and ArgTrp. With Arg-2-naphthylamide, however, the activating effect of 0.2 m Cl^? was severalfold. The hydrophobicity of the C-terminal residue of the substrate seemed to play an important role both in the Cl^? effect and substrate catalysis. Substrate binding, however, also depended on the charged groups of the substrate. Evidently Arg-2-naphthylamide and the peptides were hydrolyzed at the same active center but the mechanisms involved in the hydrolyses of chromogenic substrates and peptides may be different. It was also concluded that the less specific Cl^?-activated enzyme from human erythrocytes does not belong to the same group of Cl^?-activated arginine aminopeptidases that show a narrow substrate specificity.     

ABA分解代谢及其代谢关键酶——8'-羟化酶

脱落酸(ABA)在植物的生长发育和环境胁迫响应等过程中具有重要作用。ABA合成与分解代谢的动态平衡共同调控植物内源ABA水平。ABA8′位甲基羟基化途径是高等植物内源ABA代谢的主要途径;8′-羟化酶是该代谢途径的关键酶,属于P450酶系。生物化学和基因组学研究表明,拟南芥CYP707A家族基因编码8′-羟化酶,该基因家族广泛存在于高等植物中,调控植物内源ABA代谢,介导ABA相关的生理生化过程。本文综述了ABA分解代谢的基本途径,详细概述了ABA8′位甲基羟基化途径及该代谢途径的关键酶8′-羟化酶。同时介绍了8′-羟化酶编码基因-CYP707A家族基因的生物学特征和功能。     

Effect of estrogen on lysosomal enzyme activities in rat heart

The activities per microgram DNA of five lysosomal enzymes [cathepsin D, cathepsin B, beta-N-acetylglucosaminidase (beta-NAG), beta-glucuronidase, and acid phosphatase] were measured in homogenates of female and male rat (Sprague-Dawley) hearts. Female rats were studied during stages of the estrous cycle and at 3 weeks after ovariectomy. Three-week-postovariectomized female rats and intact male rats were injected subcutaneously with 17 beta-estradiol-3-benzoate. Lysosomal enzyme activities in the male rat heart were more responsive to exogenous estradiol than were activities in the female rat heart. Cathepsin B, beta-NAG, and beta-glucuronidase were increased dramatically in the male rat heart upon short-term administration of estrogen (4 days). In both female and male rat hearts, activities of two lysosomal proteinases, cathepsins B and D, were reduced significantly (approximately 50%) by extended administration of estrogen for 10 days.     

Mitochondrial and cytosolic localization of a single glycerate kinase in rat kidney cortex.

The distribution of glycerate kinase [ATP:D-glycerate 2-phosphotransferase, EC 2.7.1.31] in kidney was studied. This enzyme was found to be present in the renal cortex. By differential centrifugation of the homogenate and sucrose density gradient analysis, it was found that 42% and 60% of the renal glycerate kinase were localized in the cytosol and mitochondria, respectively. The mitochondrial enzyme appeared to be present in the inner membrane and/or matrix. No difference was found between the solubilized-mitochondrial and cytosolic glycerate kinase as regards kinetic properties, thermal stability, electrochemical properties, and molecular size. Immunochemical identity of these enzymes was demonstrated using a rabbit antibody against mitochondrial glycerate kinase purified from rat liver. Although the hepatic enzyme was induced by dietary protein (Kitagawa, Y., Katayama, H., & Sugimoto, E. [1979] Biochim. Biophys. Acta 582, 260--275), the renal enzyme in mitochondria and cytosol was not affected by dietary protein. These results on renal glycerate kinase are compared with those for the hepatic enzyme, and the regulatory mechanism for intracellular distribution of the enzymes is discussed.