A new method for the preparation of rat liver lysosomes. Separation of cell organelles of rat liver by carrier-free continuous electrophoresis

A combination of differential centrifugation and carrier-free continuous electrophoresis is introduced as a new method for the isolation of animal cell organelles. Various buffers were systematically checked in order to find the system which preserves the organelles and gives as well a good separation in the free-flow electrophoresis apparatus. Triethanolamine-acetate buffer (10 mM), pH 7.4 was used. The isolated lysosomes were pure according to marker enzymes and electron micrographs. A heterogeneity of the lysosomes in electrophoretic mobility was demonstrated with respect to the marker enzymes arylsulfatase and β-glucuronidase. The lysosomes with higher mobility showed a maximum enrichment of 240-fold with respect to arylsulfatase. The lysosomes with lower electrophoretic mobility showed a 65-fold enrichment with respect to β-glucuronidase. The ratio of β-glucuronidase to arylsulfatase varied from 2:1 to 1:2 in lysosomes of different mobility. The yield amounted to approximately 1 mg of lysosomal protein per gram of liver protein. 5–8 mg of lysosomes can be obtained in one experiment. The electrophoretic separation proves to be an effective tool in obtaining pure and well preserved lysosomes.     

A simple procedure for the isolation of highly purified lysosomes from normal rat liver

A procedure for the isolation of highly purified lysosomes from normal rat liver is described. The method depends on the swelling of mitochondria when the postnuclear supernatant fraction is incubated with 1 mM Ca2+. The lysosomes can then be separated from the swollen mitochondria by Percoll density gradient centrifugation. The lysosomal fraction obtained by our method was enriched more than 120-fold in terms of the marker enzymes with a yield of 25%. The electron microscopic examination and the measurement of the activities of marker enzymes for various subcellular organelles indicated that our lysosomal preparation was essentially free from contamination by other organelles.     

Isolation of hepatocyte-derived rat liver lysosomal fractions

Colloidal gold is accumulated in much smaller concentrations in lysosomes of hepatocytes of the ‘dense body’ type than in the larger lysosomes of sinus endothelial cells. These differences were used for labeling of lysosomal subpopulations as well as for the isolation of a hepatocytederived lysosomal subpopulation by combined differential and density gradient centrifugation. The origin of isolated lysosomes was determined by measurements of the gold-grain content and by cytomorphometric analyses giving size distribution curves of lysosomal profiles before and after isolation. The specific activities of β-galactosidase, acid phosphatase and especially of β-N-acetyl-glucosaminidase and β-glucuronidase were lower in lysosomal subfractions derived mainly from hepatocytes than in a mixed lysosomal fraction containing both lysosomes from hepatocytes and sinus endothelial cells.     

Studies of programmed salivary gland regression during larval-pupal transformation in Chironomus thummi: I. Acid hydrolase activity

As the salivary gland breaks down during larval-pupal transformation it displays a sharp and significant increase in the activity of p-nitrophenylphosphatase and β-glycerophosphatase. These increases are not due to concurrent enzyme synthesis, but to the activation of pre-existing enzyme or enzymes. These events parallel the breakdown of lysosomes.     

Rat-kidney lysosomes: isolation and properties

1. The activities of lysosomal enzymes in the cortexes and medullas and the principal subcellular fractions of rat kidney were measured. 2. A method is described for the isolation of rat-kidney lysosomes and a detailed analysis of the enzymic composition of the lysosomes is reported. Enzyme analysis of the other principal subcellular fractions is included for comparison. 3. Studies of the distribution of α-glucosidase showed that the lysosomal fraction contained only 10% of the total enzyme activity. The microsomal fraction contained most of the particulate α-glucosidase. Lysozyme was concentrated mainly in the lysosomal fraction with only small amounts present in the microsomal fraction. Lysosomal α-glucosidase had optimum pH5 whereas the microsomal form had optimum pH6. Both lysosomal and microsomal lysozyme had optimum pH6·2. 4. The stability of lysosomal suspensions was studied. Incubation at 37° and pH7 resulted in first an increased availability of enzymes without parallel release of enzyme. This was followed by a second stage during which the availability of enzymes was closely related to the release of enzymes. These changes were closely paralleled by changes in light-scattering properties of lysosomes. 5. The latent nature of the α-glucosidase and lysozyme of intact kidney lysosomes was demonstrated by their graded and parallel release with other typical lysosomal enzymes. 6. Isolated lysosomes were unstable at pH values lower than 5, most stable at pH6–7 and less stable at pH 8–9. Lysosomes were not disrupted when the osmolarity of the suspending medium was decreased from 0·6m to 0·25m. 7. The discussion compares the properties and composition of kidney lysosomes, liver lysosomes and the granules of macrophages. 8. The possible origin of the lysozyme in kidney lysosomes by reabsorption of the lysozyme in blood is discussed.     

Autophagic vacuoles are enriched in amyloid precursor protein-secretase activities: implications for beta-amyloid peptide over-production and localization in Alzheimer's disease

In Alzheimer’s disease (AD), the neuropathologic hallmarks of β-amyloid deposition and neurofibrillary degeneration are associated with early and progressive pathology of the endosomal–lysosomal system. Abnormalities of autophagy, a major pathway to lysosomes for protein and organelle turnover, include marked accumulations of autophagy-related vesicular compartments (autophagic vacuoles or AVs) in affected neurons. Here, we investigated the possibility that AVs contain the proteases and substrates necessary to cleave the amyloid precursor protein (APP) to Aβ peptide that forms β-amyloid, a key pathogenic factor in AD. AVs were highly purified using a well-established metrizamide gradient procedure from livers of transgenic YAC mice overexpressing wild-type human APP. By Western blot analysis, AVs contained APP, βCTF - the β-cleaved carboxyl-terminal domain of APP, and BACE, the protease-mediating β-cleavage of APP. β-Secretase activity measured against a fluorogenic peptide was significantly enriched in the AV fraction relative to whole-liver lysate. Compared to other recovered subcellular fractions, AVs exhibited the highest specific activity of γ-secretase based on a fluorogenic assay and inhibition by a specific inhibitor of γ-secretase, DAPT. AVs were also the most enriched subcellular fraction in levels of the γ-secretase components presenilin and nicastrin. Immunoelectron microscopy demonstrated selective immunogold labeling of AVs with antibodies specific for the carboxyl termini of human Aβ40 and Aβ42. These data indicate that AVs are a previously unrecognized and potentially highly active compartment for Aβ generation and suggest that the abnormal accumulation of AVs in affected neurons of the AD brain contributes to β-amyloid deposition.     

Proton-translocating ATPase and lysosomal cystine transport

A proton-translocating ATPase was identified in highly purified lysosomes from Epstein-Barr virus-transformed human lymphoblasts. Activity of this ATPase caused acidification of highly purified, fluorescein isothiocyanate dextran-loaded lysosomes and correlated with the ATP-dependent efflux of lysosomal cystine. The lysosomal ATPase was distinct from mitochondrial F1-ATPase in its responses to a variety of inhibitors. Although ATP-dependent lysosomal cystine efflux is not demonstrable in cultured lymphoblasts from individuals with nephropathic cystinosis, ATPase activity and acidification in lysosomes from these cells is comparable to that in noncystinotic lysosomes. ATPase activity in lymphoblasts from normal individuals was 543 +/- 79 nmol/mg/min while in lymphoblasts from cystinotic individuals this activity was 541 +/- 25 nmol/mg/min. ATP-dependent acidification of lysosomes from normals was -0.5 +/- 0.1 pH units compared to -0.5 +/- 0.1 pH units in cystinotic lysosomes. Activity of the lysosomal proton-translocating ATPase is a necessary, but not sufficient, condition for lysosomal cystine efflux.     

Improved recovery of rat liver fractions enriched in lysosomes by specific alteration of the sedimentation properties of mitochondria

A method for the preparation of lysosomes from rat liver is presented. The procedure requires only standard equipment and is completed within less than 3 h. Homogenization and differential centrifugation were performed at pH 7.4 in isotonic potassium phosphate-buffered sucrose medium. The addition of potassium phosphate, at the concentration used (10 mM), accelerated the sedimentation rate of mitochondria without altering that of lysosomes resulting in the decrease in the mitochondrial contamination of the final pellet. Further purification was achieved by isopycnic centrifugation in 45% isotonic Percoll performed in an angle rotor. Lysosomal fractions representing 51.5% of the original population were recovered over a density range of 1.09 to 1.15 g/ml. The most purified fraction (37-fold purified) contained 25.3% of lysosomal beta-N-acetylglucosaminidase, and only 0.9% of mitochondrial monoamine oxidase and 0.6% of peroxisomal urate oxidase original activities. It was practically devoid to endoplasmic reticulum contamination.     

Biological Time-Related Changes in Tolerance of Male Mice to Hypoxia—II. Orcadian Rhythm of Lysosomal Susceptibility to Hypoxia

Circadian variations of mouse liver, brain and heart lysosomal susceptibility to hypoxia were investigated. Lysosomal disruption during hypoxia was estimated on the basis of the following measurements: changes in percentage free activity of β-galactosidase and acid phosphatase, tissue loss of both lysosomal enzymes and accumulation of serum β-galactosidase. When exposure to hypoxia took place at the end of the rest phase or at the beginning of the active phase, it was accompanied by maximum increase of percent free activity. This, presumably represents a diffusion of enzymes from lysosomes due to altered membrane permeability. However, hypoxia when occurring during the second part of the active phase and first part of the rest phase resulted in tissues loss of lysosomal enzymes and accumulation of serum lysosomal enzymes. This is believed to represent the release of lysosomal enzymes in bulk from damaged or ruptured lysosomal membranes.     

The activator of cerebroside sulphatase. Lysosomal localization.

1) An activator protein necessary for the enzymic hydrolysis of cerebroside sulphate could be partially purified from unfractionated rat liver. This activator, which is similar to that of human origin, proved to be a heat-stable, non-dialyzable, low molecular weight protein with an isoelectric point of 4.1. Its activity could be destroyed by pronase. 2) For elucidation of the subcellular localization of the activator, rat liver was fractionated by differential centrifugation. The intracellular distribution of the cerebroside sulphatase activator was compared to the distribution patterns of marker enzymes for different cell organelles and found to coincide with the lysosomal arylsulphatase, thus indicating a lysosomal localization. 3) This was confirmed using highly purified secondary, i.e. iron-loaded, lysosomes. After disruption by osmotic shock, these organelles hydrolyzed cerebroside sulphate when incubations were performed under physiological conditions with endogenous as well as exogenous sulphatase A as enzyme. 4) After subfractionation of the disrupted secondary lysosomes into membrane and lysosol fractions by high speed centrifugation, it was found that the activator protein was exclusively associated with the lysosol, whereas the acid hydrolases were distributed differently between the two fractions. 5) The lysosol was further fractionated by semi-preparative electrophoresis on polyacrylamide gels. Two protein fractions were obtained: a high molecular weight fraction, containing the activator-free acid hydrolases, and a low molecular weight fraction, containing the enzyme-free activator of cerebroside sulphatase. 6) The significance of these findings for the hydrolysis of sphingolipids in the lysosomes is discussed.     

Isolation of rat liver lysosomes by isopycnic centrifugation in a metrizamide gradient

A preparation, similar to the light mitochondrial fraction of rat liver (L fraction of de Duve et al, (1955, Biochem. J. 60: 604-617), was subfractionated by isopycnic centrifugation in a metrizamide gradient and the distribution of several marker enzymes was established. The granules were layered at the top or bottom of the gradient. In both cases, as ascertained by the enzyme distributions, the lysosomes are well separated from the peroxisomes. A good separation from mitochondria is obtained only when the L fraction if set down underneath the gradient. Taking into account the analytical centrifugation results, a procedure was devised to purify lysosomes from several grams of liver by centrifugation of an L fraction in a discontinuous metrizamide gradient. By this method, a fraction containing 10--12% of the whole liver lysosomes can be prepared. As inferred from the relative specific activity of marker enzymes, it can be estimated that lysosomes are purified between 66 and 80 times in this fraction. As ascertained by plasma membrane marker enzyme activity, the main contaminant could be the plasma membrane components. However, cytochemical tests for 5'AMPase and for acid phosphatase suggest that a large part of the plasma membrane marker enzyme activity present in the purified lysosome preparation could be associated with the lysosomal membrane. The procedure for the isolation of rat liver lysosomes described in this paper is compared with the already existing methods.     

Intercellular exchange of lysosomal hydrolases between mutant human fibroblasts and other cell types

Human fibroblasts with a genetic deficiency of a single lysosomal enzyme and fibroblasts from a patient with ‘I-cell’ disease with a multiple deficiency of lysosomal hydrolases were used as recipient cells in studies on recognition and uptake of β-N-acetylhexosaminidase (hexosaminidase), β-glucuronidase and β-galactosidase. Normal human fibroblasts, and fibroblasts, hepatocytes and hepatoma cells from the rat were used as donor cells. The release of hexosaminidase was found to be similar among these different cell types, but the extracellular activities of β-glucuronidase and β-galactosidase were much higher in the rat cell cultures than in cultures of normal human fibroblasts. The enzymes released by rat fibroblasts were ingested by deficient human fibroblasts; enzyme from normal human fibroblasts was shown to be taken up by rat fibroblasts by means of electrophoresis. This indicates that reciprocal transfer of lysosomal hydrolases occurs between human and rat fibroblasts. Rat hepatocytes released hydrolases that were poorly taken up by human recipient fibroblasts and uptake of human fibroblast enzyme was not detected in the hepatocytes. Rat hepatoma cells, on the other hand, released lysosomal enzymes that were taken up by human deficient cells with a higher efficiency than those from fibroblasts. The uptake was subject to competitive inhibition by mannose 6-phosphate, the kinetics of which were comparable with those reported for ‘high-uptake’ forms of lysosomal enzymes [1–2]. Electrophoretic studies showed that rat hepatoma cells were not only capable of ingesting hexosaminidase from normal human fibroblasts, but also defectively processed enzyme [4–5] released by ‘I-cells’. These findings make rat hepatoma cells a useful model for the study of recognition and uptake of lysosomal enzymes.     

Enzyme markers and isolation of the microvillar and perimicrovillar membranes of Dysdercus peruvianus (hemiptera: pyrrhocoridae) midgut cells

The midgut of Dysdercus peruvianus is divided into four sections (V₁-V₄). All the cells have microvilli ensheathed by a lipoprotein membrane (perimicrovillar membrane) extending toward the lumen as narrow tubes with dead ends. Subcellular fractionation of V₁ and V₂ tissue in isotonic and hypotonic conditions showed that -glucosidase is associated with membranous structures larger than those associated with β-glucosidase. The /β-glucosidase activity ratio is 34 ± 4 in V₁ tissue and 170 ± 10 in membranes recovered from the V₁ luminal contents. These membranes are resolved in sucrose gradients into low density (1.087 ± 0.001 g/cm³) -glucosidase-carrying membranes (/β-glucosidase activity ratio of 330±30) and high density (1.132 ± 0.002g/cm³) β-glucosidase-carrying-membranes. Low-density membranes have 1090 ± 60 μg lipid/mg protein and apparently are not contaminated by high-density ones (electron micrographs). SDS-polyacrylamide gel electrophoresis (SDS-PAGE) showed that membranes recovered from V₁ luminal contents are composed mainly of a-glucosidase-rich membranes. The data suggest that -glucosidase-rich membranes are perimicrovillar membranes which may be partly lost into luminal contents on dissection, with densities and lipid/protein ratios similar to that of myelin sheaths, in accordance with previous freeze-fracture data. β-Glucosidase-rich membranes are probably microvillar membranes with densities increased by the presence of associated portasomes.     

Purification and chemical characterization of thermostable amylases produced by Bacillus stearothermophilus

The amylases produced by a Bacillus stearothermophilus were purified through a series of four steps. Two separable enzyme fractions having starch hydrolysing activity were eluted from a DEAE-cellulose column by NaCl gradient elution. The homogeneity of the purified enzymes was checked on polyacrylamide gel electrophoresis. The product formation studies indicated that fraction I was an -amylase whereas fraction II was a β-amylase. The molecular weights were determined to be 48 000 and 57 000 and the carbohydrate moiety was found to be 13.2 and 0.8% for - and β-amylase, respectively. The protein digest of these enzymes indicated a total number of 15 amino acids with aspartic and glutamic acid showing the highest value. The purified amylase showed maximal activity at 80°C and pH 6.9. Fe³⁺, Cd²⁺, Pb²⁺, Hg²⁺, Ni²⁺ and Ag¹⁺ were potent inhibitors whereas Zn²⁺, Mg²⁺, Mn²⁺ and Al³⁺ were mild inhibitors. Ca²⁺, Ba²⁺, Sr²⁺ and K⁺ stimulated amylase activity in the order of Ca²⁺ > Ba²⁺ > Sr²⁺ > K⁺. PCMB, EDTA and sodium iodoacetate were inhibitory whereas glutathione (GSH) and cysteine afforded protection of enzyme activity. EDTA showed dose-dependent noncompetitive inhibition of both - as well as β-amylase activities. EDTA inhibition was reversed by the addition of Ca²⁺ and PCMB inhibition by the addition of glutathione (reduced). The K_m for - and β-amylases were found to be 1.05 and 1.25 mg starch per ml, respectively.     

Receptors for gonadotropins and prostaglandins in lysosomes of bovine corpora lutea.

The total mitochondrial fraction of bovine corpus luteum specifically bound [³H]prostaglandin (PG) E₁, [³H] PGF_2α, and ¹²⁵I-labeled human lutropin (hLH) despite very little 5′-nucleotidase activity, a marker for plasma membranes. Since the total mitochondrial fraction isolated by conventional centrifugation techniques contains both mitochondria and lysosomes, it was subfractionated into mitochondria and lysosomes to ascertain the relative contribution of these fractions to the binding. Subfractionation resulted in an enrichment of cytochrome c oxidase (a marker for mitochondria) in mitochondria and of acid phosphatase (a marker for lysosomes) in lysosomes. The lysosomes exhibited little or no contamination with Golgi vesicles, rough endoplasmic reticulum, or peroxisomes as assessed by their appropriate marker enzymes. Subfractionation also re ulted in [³H] PGE₁, [³H] PGF_2α, and ¹²⁵I-labeled hLH binding enrichment with respect to homogenate in lysosomes but not in mitochondria. The lysosomal binding enrichment and recovery were, however, lower than in plasma membranes. The ratios of marker enzyme to binding, an index of organelle contamination, revealed that plasma membrane and lysosomal receptors were intrinsic to these organelles. Freezing and thawing had markedly increased lysosomal binding but had no effect on plasma membrane binding. Exposure to 0.05% Triton X-100 resulted in a greater loss of plasma membrane compared to lysosomal binding. In summary, the above results suggest that lysosomes, but not mitochondria, in addition to plasma membranes, intrinsically contain receptors for PGs and gonadotropins. Furthermore, lysosomes overall contain a greater number of PGs and gonadotropin receptors compared to plasma membranes and these receptors are associated with the membrane but not the contents of lysosomes.     

Isolation and properties of lysosomes from dark-grown potato shoots

Summary A method is described for the isolation of lysosomal fractions from dark-grown potato shoots using a single stage separation on a Ficoll gradient. Peaks of acid hydrolase activity consisting of acid phosphatase, phosphodiesterase, ribonuclease, carboxylic esterase and -glycerophosphatase were well separated from peaks of mitochondrial and glyoxysomal enzymes. A heavy lysosomal fraction with particle diameters from 0.1 to 1.6 and density of 1.10 g cm^-3 containing relatively low hydrolase activity was distinguishable from a light fraction with diameters 0.025 to 0.6 and density of 1.07 g cm^-3 with a higher level of hydrolase activity. Both fractions appeared heterogeneous by electron microscopy, but the fine structure of the membranes of both heavy and light lysosomes was similar. The heavy lysosomal fraction was rich in autophagic vacuoles (secondary lysosomes) containing organelles and amorphous cytoplasmic material. Both fractions were rich in ribonucleic acid.Freezing and thawing, high speed blending and ultrasonication either singly or in combination solubilised a maximum of ca. 30% of the acid phosphatase from crude lysosomal fractions derived from dark-grown potato shoots. Treatment with Triton X-100 and deoxycholate released appreciably more enzyme activity but acetone and carbon tetrachloride failed to solubilise any acid phosphatase. Only detergent treatments gave marked overrecovery of enzyme and indicated structure-linked latency. Liberation of enzyme from lysosomes varied with pH and was almost complete at both extremes of pH. Crude snake venom was rapid and effective in solubilising acid phosphatase from lysosomal preparations, purified phospholipase A was less effective and phospholipases C and D had negligible effects. Phospholipase and venom mediated release of acid phosphatase was accompanied by the coincident release of an acid end-product. Gel filtration of acid phosphatase liberated from heavy and light lysosomal fractions by snake venom digestion revealed that each of these fractions was characterised by the presence of distinct molecular forms of the enzyme. The nature of the association of acid phosphatase with potato shoot lysosomes is discussed.     

Cell surface-associated lysosomal enzymes in cultured human skin fibroblasts

Trypsin released from the surface of intact human skin fibroblasts β-N-acetylglucosaminidase. The amount of trypsin removable β-N-acetylglucosaminidase in 4 control and 14 mucopolysaccharidosis cell lines was equivalent to 1.5% (range 0.5–4.3%) of the intracellular activity. Cell surface-associated β-N-acetylglucosaminidase was absent in mucolipidosis II and III fibroblasts that form lysosomal enzymes defective in binding to the cell surface receptors of fibroblasts and in β-N-acetylglucosaminidase deficient fibroblasts (Sandhoff's disease). Indirect immunofiuorescence with monospecific antisera allowed the demonstration of β-N-acetylglucosaminidase, α-N-acetylglucosaminidase, α-mannosidase and β-glucuronidase on the cell surface of fibroblasts, whereas these enzymes were absent on the cell surface of mucolipidosis II and III fibroblasts. Simultaneous staining for β-glucuronidase and β-N-acetylglucosaminidase showed presence of both enzymes in almost identical areas of the same cell. Cross-reacting material was present on the cell surface of fibroblasts with a deficiency of β-N-acetylglycosaminidase, α-N-acetylglucosaminidase (mucopolysaccharidosis III B), α-mannosidase (mannosidosis) and β-glucuronidase (mucopolysaccharidosis VII). The demonstration of lysosomal enzymes on the cell surface is in agreement with the hypothesis that in fibroblasts transport of lysosomal enzymes to the lysosomal apparatus involves cycling of lysosomal enzymes via the cell surface.     

Synthesis and intracellular localization of chick acid α-glucosidase in chick erythrocyte-human fibroblast heterokaryons : A model system for the study of lysosomal enzyme synthesis

The synthesis and localization of chick acid α-glucosidase has been studied in chick erythrocyte-human fibroblast heterokaryons. Monospecific antibodies raised against purified chick liver acid α-glucosidase were used. It was found that the acid α-glucosidase in the heterokaryons is of chick origin, and is localized in the same lysosomes as the human lysosomal enzymes. It is concluded that chick erythrocyte-human fibroblast heterokaryons provide a useful model system for the study of lysosomal enzyme synthesis and routing.     

Identification of two subpopulations of thyroid lysosomes: relation to the thyroglobulin proteolytic pathway.

Using a combination of differential centrifugation and isopycnic centrifugation in Percoll gradients, we obtained a highly purified preparation of thyroid lysosomes [Alquier, Guenin, Munari-Silem, Audebet & Rousset (1985) Biochem. J. 232, 529-537] in which we identified thyroglobulin. From this observation, we postulated that the isolated lysosome population could be composed of primary lysosomes and of secondary lysosomes resulting from the fusion of lysosomes with thyroglobulin-containing vesicles. In the present study, we have tried to characterize these lysosome populations by (a) subfractionation of purified lysosomes using iterative centrifugation on Percoll gradients and (b) by functional studies on cultured thyroid cells. Thyroglobulin analysed by soluble phase radioimmunoassay, Western blotting or immunoprecipitation was used as a marker of secondary lysosomes. The total lysosome population separated from other cell organelles on a first gradient was centrifuged on a second Percoll gradient. Resedimented lysosomes were recovered as a slightly asymmetrical peak under which the distribution patterns of acid hydrolase activities and immunoreactive thyroglobulin did not superimpose. This lysosomal material (L) was separated into two fractions: a light (thyroglobulin-enriched) fraction (L2) and a dense fraction (L1). L1 and L2 subfractions centrifuged on a third series of Percoll gradients were recovered as symmetrical peaks at buoyant densities of 1.12-1.13 and 1.08 g/ml, respectively. In each case, protein and acid hydrolase activities were superimposable. The specific activity of acid phosphatase was slightly lower in L2 than in L1. In contrast, the immunoassayable thyroglobulin content of L2 was about 4-fold higher than that of L1. The overall polypeptide composition of L, L1 and L2 analysed by polyacrylamide-gel electrophoresis was very similar, except for thyroglobulin which was more abundant in L2 than in either L or L1. The functional relationship between L1 and L2 lysosome subpopulations has been studied in cultured thyroid cells reassociated into follicles. Thyroid cells, prelabelled with 125I-iodide to generate 125I-thyroglobulin, were incubated in the absence of in the presence of inhibitors of intralysosomal proteolysis. The fate of 125I-thyroglobulin, and especially its appearance in the lysosomal compartment, was studied by Percoll gradient fractionation and immunoprecipitation. Treatment of prelabelled thyroid cells with chloroquine and leupeptin induced the accumulation of immunoprecipitable 125I-thyroglobulin into a lysosome fraction corresponding to the L2 subpopulation. In control cells, in which intralysosomal proteolysis was n     

Bovine seminal ribonuclease: Non-hyperbolic kinetics in the second reaction step

Peroxisomes contain enzymes catalyzing the β-oxidation of fatty acids, which have been purified and partially characterized. Hypolipidemic drugs, including clofibrate, cause a marked proliferation of peroxisomes and a striking increase in the activity of their β-oxidation system. We have compared by sodium dodecyl sulfate—polyacrylamide gel electrophoresis the polypeptide patterns of normal and clofibrate-induced peroxisomes and the purified β-oxidation enzymes. The data allow a tentative identification of the β-oxidation enzymes among the peroxisomal polypeptides; these enzymes constitute only a small part of the protein of normal peroxisomes. A subset of peroxisomal polypeptides, including the β-oxidation enzymes, is preferentially increased by clofibrate.