Brain lysosomal hydrolases: I. Solubilization and electrophoretic behavior of acid hydrolases in nerve-ending and mitochondrial-lysosomal fractions from rat brain. Effects of autolysis,neuraminidase, and storage

In solubility studies of 7 acid hydrolases, the extent of solubilization by sonic disruption varied with the enzyme species and increased with increasing pH and Triton X-100 concentration of the suspension medium. Hydrolases in the nerve-ending (NE) fraction were more resistant to solubilization than those in the mitochondrial-lysosomal (M-L) fraction, but nearly quantitative solubilization was attained by sonication in an alkaline buffer containing 0,5% Triton X-100. Polyacrylamide gel electrophoresis of extracts revealed multiple components of acid phosphatase, acid esterase, arylsulfatase,-glucuronidase, and-N-acetyl-hexosaminidase. The enzyme patterns varied with the subcellular fraction and the composition of the medium. In general, the acidic (anodic) forms of these hydrolases were more readily solubilized by sonication in acidic buffer, alkaline pH and Triton X-100 being required to solubilize the basic (cationic) components. The acidic forms of these enzymes were converted to less anodic or cathodic forms, or both, during autolysis at pH 6 at 0 and 37°C, and during storage at –20°C.     

Latency of acid hydrolases in rat kidney cortex

1. Some lysosomal populations in the rat kidney cortex appear to be mechanically weak and are readily disrupted by gentle homogenization, while other populations remain intact even after repeated homogenization. 2. Lysosomes in the rat kidney cortex appear to be resistant to hypertonic media but are readily disrupted under hypotonic conditions. 3. Lysosomes in rat kidney cortex are readily disrupted when incubated in isotonic sucrose at 37 degrees C. 4. Measurement of total and free activity of three acid hydrolases: N-acetyl-beta-D-glucosaminidase (NAG), acid beta-galactosidase and acid beta-glycerophosphatase, indicates that the latency of these enzymes is relatively low in the homogenate (10-29%) and the ML-fraction (14-42%), but high (60-95%) in the purified large lysosomes (protein droplets). 5. The latency of purified small lysosomes is relatively lower (30-60%) than that of large lysosomes, suggesting that small lysosome populations are relatively permeable to the acid hydrolase substrates. 6. Latency variations of acid hydrolases amongst subcellular fractions appear to reflect the heterogeneity of lysosomal populations present in the kidney cortical homogenate.     

Dual localization of acid hydrolases in endoplasmic reticulum and in lysosomes

Summary Dissimilar enzyme locations obtained on occasion by the post- and simultaneous-coupling techniques employing the substrate naphthol AS-BI -glucosiduronic acid were attributed to the inadequate incorporation of substrate into lysosomal membranes in the post-coupling technique on the one hand, as well as to the inhibition of cytoplasmic enzyme by diazotate in the simultaneous coupling technique on the other hand. The use of a fixative solvent mixture prior to the enzyme staining reaction appeared to labilize lysosomal membranes, to improve fixation and to eliminate fiber artefacts. In male mice which have been androgenized by the injection of gonadotrophin, kidney homogenates, subsequently prepared, exhibited an immediate increase in the specific activity of microsomal -glucuronidase while lysosomal -glucuronidase was unchanged for the first 36 hours.This event at 36 hours corresponded with enhanced cytoplasmic but not lysosomal staining. Diffuse reactions in enzyme morphology are discussed as well as the origin of lysosomal -glucuronidase in mouse kidney and the dual localization of hydrolases in endoplasmic reticulum and lysosomes.     

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

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

Effect of neuraminidase on the chromatographic behaviour of eleven acid hydrolases from human liver and plasma.

1. The elution profiles of eleven acid hydrolases from human liver and plasma were directly compared using a system whereby a single salt gradient was simultaneously applied to two DEAE-cellulose chromatographic columns. 2. Plasma alpha-L-fucosidase, alpha-mannosidase, alpha-galactosidase and alpha-glucosidase isoenzymes were eluted at higher salt concentrations than the corresponding liver isoenzymes whereasbeta-N-acetylglucosaminidase, beta-galactosidase, beta-glucosidase, exo-1,4-beta-xylosidase and alpha-L-arabinofuranosidase isoenzymes were eluted at lower salt concentrations. The elution profiles of beta-glucuronidase and acid phosphatase weremore complex. 3. After incubation with neuraminidase most plasma hydrolases were eluted at lower salt concentrations, however the elution patterns of beta-glucosidase, beta-xylosidase and acid phosphatase were not altered. 4. Preincubation with neuraminidase had no effect on the elution profiles of six liver hydrolases whereas the major isoenzymes of alpha-mannosidase, beta-galactosidase and alpha-L-arabinofuranosidase were eluted at markedly lower salt concentrations. Liver alpha-fucosidase and alpha-galactosidase were eluted at slightly lower salt concentrations afterincubation with neuraminidase. 5. The results are discussed in relation to thepathogenesis of Mucolipidosis II (I-cell disease), and the synthesis and packaging of lysosomal enzymes.     

The effect of cephaloridine on the stability of rat kidney lysosomes.

The administration of cephaloridine to rats caused a decrease in the excretion of acid phosphatase into the urine. The antibiotic itself had no effect on urinary acid phosphatase and inhibitors or proteolytic enzymes were not present in the urine from treated rats. Cephaloridine may therefore be stabilizing the lysosomal membrane in vivo and experiments with isolated lysosomes confirm this hypothesis. The lysosomal integrity was followed by measuring the acid phosphatase activity and the light scattering properties of the particles. A good correlation was obtained between these parameters in the case of thermal disruption and progesterone induced lysis of the lysosomes and low concentrations of cephaloridine (0.1-1.0 mmol/1) protected the lysosomes against this form of damage.     

Influence of optical density on the automated segmentation of rat kidney lysosomes.

After staining for acid phosphatase, video-images were acquired from 0.5-micron sections of rat kidney. Lysosomes in proximal tubules were automatically segmented, using a VICOM digital image processor and measured for area, number and optical density (OD). The purpose of this study is to objectively evaluate the performance of the automated segmentation algorithm at different staining intensities (a) by measuring area after staining with different incubation times, reduced substrate concentration or by adding an inhibitor and (b) by 'simulating' a decrease in OD (reducing grey-values at each point of a digitized image). The results of the experiments showed that: (1) the algorithm will underestimate the size of lysosomes (a) when the OD in close to the local background and (b) when an area is larger than or close to the area of the lowpass square filter; (2) accuracy of the segmentation can be improved by comparing the results of feature extraction after segmentation of the same image at different relative OD levels; (3) lysosomes with very low OD, compared to background are delineated with a large error or not delineated at all and this cannot be corrected. Incorrectly delineated lysosomes can be identified and excluded from further calculations, or their measured area replaced by an estimate of the true area.     

The interaction of cephaloridine with model membrane systems and rat kidney lysosomes.

The antibiotic cephaloridine has been shown to interact with phospholipid structures, using the techniques of ultraviolet difference spectroscopy, surface pressure measurements and liposome models. The results indicate that this interaction is at least partly hydrophobic in nature and help explain the disruptive effects of high concentrations of cephaloridine on both artificial and natural phospholipid structures (lysosomes). Low concentrations of cephaloridine were shown to inhibit a lysosomal membrane-bound phospholipase 2 and it is suggested that such an inhibition may explain the cephaloridine-induced stabilization of rat-kidney lysosomes.     

Renal neuraminidase. Characterization in normal rat kidney and measurement in experimentally induced nephrotic syndrome.

Several lines of evidence suggest that increased neuraminidase activity may be responsible for the loss of glomerular N-acetylneuraminic acid (AcNeu) observed in various glomerular diseases. However, virtually no information is available on the activity of neuraminidase in glomeruli or the potential role of this enzyme in glomerular pathophysiology. Utilizing 2'-(4-methylumbelliferyl)-alpha-D-N-acetylneuraminic acid (4MU-AcNeu) as substrate, we defined optimal assay conditions and characterized neuraminidase activity in glomeruli and, for comparison, in other renal fractions and liver. Neuraminidase activity in glomeruli, cortex and tubules was maximal at pH 4.4. The Km for 4MU-AcNeu was estimated to be 195 microM for glomeruli and 226 microM for cortex. Glomerular neuraminidase was inhibited by AcNeu (90% at 25 mM) and high concentrations of Triton X-100 (26% at 0.5%), but unaffected by CaCl2, EDTA or N-ethylmaleimide (each 1 mM). Neuraminidase activity (nmol/h per mg of protein; mean +/- S.E.M.) in normal rat kidney was: cortex, 14.47 +/- 0.76; medulla, 7.85 +/- 0.64; papilla, 2.64 +/- 0.11; tubules, 13.79 +/- 0.70; glomeruli, 5.57 +/- 0.28. In comparison, neuraminidase activity in rat liver was 2.58 +/- 0.14. Puromycin aminonucleoside (PAN)-induced nephrotic syndrome is a model of glomerular disease in which the loss of glomerular AcNeu is well documented. In two separate studies, we observed no change in the specific activity of neuraminidase in either glomeruli or cortex isolated from rats treated with PAN (15 mg/100 g, intraperitoneally) and killed at either the onset or the peak of proteinuria. Results were similar whether neuraminidase activity was expressed per mg of protein or per microgram of DNA.     

Solubilization of rat kidney lysosomes in reversed micelles of aerosol OT in octane.

Intact lysosomes from rat kidneys were solubilized in the ternary system: surfactant (Aerosol OT)-buffer-organic solvent. According to data of laser light-scattering analysis and kinetic experiments with the lysosomal marker enzyme, N-acetyl-beta-D-hexosaminidase (EC 3.2.1.30), the solubilization of lysosomes in this system resulted in the destruction of the lysosomes and the entrapping of their components in reversed micelles.