Lysosomal hydrolases in calf thyroid

1. Two acid phosphatases (β-glycerophosphatase and phenylphosphatase), acid β-glucuronidase and cathepsin were demonstrated in the 0·25m-sucrose homogenates from whole calf thyroid tissue and from isolated calf thyroid cells. 2. The main kinetic characters of these enzymes were studied. 3. All these acid hydrolases are partially sedimentable and display a latency that is unmasked by treatment with Triton X-100 and on dilution in hypo-osmotic media. It is concluded that these acid hydrolases belong to the lysosomes.     

Studies on bone enzymes. Distribution of acid hydrolases, alkaline phenylphosphatase, cytochrome oxidase and catalase in subcellular fraction of bone tissue homogenates

1. When bone homogenates were fractionated according to the scheme developed for liver by de Duve, Pressman, Gianetto, Wattiaux & Appelmans (1955), all the enzymes assayed except cytochrome oxidase were found to occur partly in soluble and partly in particulate fractions. Among the particle-bound enzymes, the highest specific activity was found in the heavy-mitochondrial fraction for cytochrome oxidase, in the microsomal fraction for alkaline phenylphosphatase and in the light-mitochondrial fraction for eight acid hydrolases and for catalase. 2. Combined heavy-mitochondrial and light-mitochondrial fractions were subfractionated by isopycnic centrifugation in density gradients of sucrose or glycogen. In the various systems tried, cytochrome oxidase showed a relatively narrow distribution range with a sharp peak; the acid hydrolases and catalase showed flat and irregular distribution patterns, differing slightly in shape from one enzyme to the other. However, it was not possible to achieve a marked separation between the various enzymes under study. 3. It is concluded from these results that the acid hydrolases belong to special cytoplasmic particles, probably lysosomes, and that these particles are physically and enzymically heterogeneous. Catalase appears to be non-mitochondrial and could also belong to the lysosomes; but the possibility of an association with another type of particle must be kept in mind in view of what is known of liver catalase. Alkaline phenylphosphatase is largely attached to microsomal elements.     

The lysosomes of earthworm chloragocytes: biochemical and morphological characterization

Nine latent and sedimentable acid hydrolases have been detected in the homogenates of earthworm chloragocytes. Their full activity was revealed by treatment with Triton X-100, a Waring blender treatment, freezing and thawing, hypotonic media or incubation at pH 5 and 25 degrees C. Solubilization paralleled the activation of the enzymes. Together with kinetic studies, these results indicate that the acid hydrolases of the chloragocytes are inside typical lysosome-like particles whose membrane is impermeable to their substrates. It could be shown by density equilibration centrifugation that the lysosomes of those cells constitute a heterogeneous population of subcellular particles distinct from the chloragosomes. Moreover, their digestive function has been directly demonstrated by the capture and degradation of serum albumin. The lysosomes of the chloragocytes have been clearly identified as polyvesicular bodies by electron microscopic analysis of the fractions obtained by density equilibration centrifugation and by examination of the whole tissue, as such or after endocytosis of serum albumin or ferritin. Finally, our results do not support a possible relationship between the lysosomes and the chloragosomes of the chloragocytes.     

Hyaluronidase activity in lysosomes of bone tissue

1. The distribution pattern of hyaluronidase in subcellular fractions of bone-tissue homogenates is closely similar to that reported by Vaes & Jacques (1965b) for the other acid hydrolases of this tissue. The highest specific activity of hyaluronidase is also found in the light-mitochondrial fraction. 2. In cytoplasmic extracts of bone, about 60% of the activity of hyaluronidase is latent, and is unmasked by a number of treatments (digitonin, low osmotic pressure, freezing and thawing, Waring Blendor) that unmask the lysosomal β-glucuronidase in a closely parallel manner. Low concentrations of Triton X-100 render a larger proportion of β-glucuronidase than of hyaluronidase accessible to external substrates, but release the same proportion of both enzymes in unsedimentable form. 3. These results support the concept of an association of hyaluronidase with lysosomes in bone.     

Characteristics of lysosomes in the rat placental cells

Six acid hydrolases, cytochrome oxidase, and alkaline phosphatase were demonstrated in 0.25 m sucrose homogenates of rat chorioallantoic placenta. The acid hydrolases were: acid phosphatase, β-glucuronidase, N-acetyl-β-glucosaminidase, β-galactosidase, and acid deoxyribonuclease, showing optimum activity near pH 4.5; cathepsin, with optimum activity near pH 3.6. The free acid hydrolases present in cytoplasmic extracts expressed 20–40% of their total activity. “Total” activity was defined as the enzyme activity observed in the presence of Triton X-100, while “free” activity denoted enzyme activity measured under similar assay conditions except in the presence of sucrose and absence of Triton X-100. The decreased activity or latency in the assays for the free activity of acid phosphatase, acid deoxyribonuclease, and cathepsin persisted after incubation at pH 5 and 37 ° up to an hour. In contrast, this latency did not persist after incubation of the β-glycosidases. Additionally, the free activity of all the designated enzymes of the cytoplasmic extract was in excess of the nonsedimentable activity observed.     

Studies on the structure-bound sedimentability of some rat liver lysosome hydrolases

1. Lysosome-rich fractions from rat liver were subjected to several disruptive procedures: osmotic lysis or freezing and thawing in different media, shearing forces in a high-speed blender, treatment with Triton X-100. 2. The soluble and particulate phases were then separated by high-speed centrifugation and assayed for their content of acid phosphatase, β-galactosidase, β-N-acetylglucosaminidase, acid proteinase, acid ribonuclease, acid deoxyribonuclease and protein. 3. The degree of elution of these hydrolases appeared to depend on both the enzyme species and the treatment. The resulting patterns of solubilization were rather complex, so that a clear-cut discrimination between soluble and structure-bound enzymes could not always be traced. 4. Although only β-galactosidase was readily solubilizable after all treatments, acid proteinase could also be extensively eluted from the sedimentable material in the presence of EDTA and acid phosphatase was fully extracted by Triton X-100. On the other hand, considerable proportions of the other activities could not be solubilized by any of the procedures used. 5. In other experiments, the adsorbability of hydrolases on subcellular structures was investigated by measuring the partition between sedimentable particles and soluble fraction of solubilized enzymes added to `intact' liver homogenates. 6. Large proportions of acid proteinase, ribonuclease and deoxyribonuclease, and almost all of β-N-acetylglucosaminidase, were found to be adsorbed on the particulate material.     

Calcium transport in isolated bone cells. I. Bone cell isolation procedures

Differential centrifugation of homogenates of Harding-Passey melanoma demonstrated that aryl sulfatase A and β-glucuronidase sediment with particles (i.e., lysosomes) distinct from those particles bearing tyrosinase (i.e., melanosomes). The sedimentation curves for the lysosomal enzymes and tyrosinase, however, demonstrated that an adequate separation of these particle types could not be obtained by differential centrifugation. Isopycnic density gradient centrifugation was used to obtain the necessary resolution. The results of the density gradient studies demonstrated that lysosomes and melanosomes could be separated by this technique, as judged by enzyme distribution among the fractions recovered from the gradients and from electron microscopic examination of the melanosome fractions. It was further evident that the purified and washed melanosomes contained significant amounts of both acid hydrolase activities. Indeed 24% to 27% of the total acid hydrolase activities recovered from the density gradients were associated with the melanosome fractions. The acid hydrolases associated with the melanosomes could not be solubilized by treatment with 0.1% (v/v) Triton X-100, nor by exposure to hypo-osmotic shock. The melanoma lysosomes, however, did release most of both their hydrolase activities into soluble form after treatment with the same percentage of detergent. The lysosomes were, however, very resistant to rupture by exposure to hypo-osmotic conditions.     

Evidence for NAD nucleosidase in rabbit-liver lysosomes.

A method is described for the isolation of secondary lysosomes from homogenates of rabbit liver; The uptake of Triton WR-1339 by rabbit-liver lysosomes when administered by intraperitoneal injection was used to decrease the density of secondary lysosomes. Lysosomal fractions prepared by this method contain an NAD nucleosidase (NAD glycohydrolase, EC 3;2.25), an enzyme which has previously been considered to be associated with other subcellular fractions. The enzyme has maximum activity at pH 6 and cleaves both NAD and NADP. It is inhibited by nicotinamide (Ki equals 4.5 mM) and by HgCl2. Both nucleosidase and 2'-nucleotidase show in-vitro latency typical of lysosomal acid hydrolases. Rabbit-liver plasma-membrane fractions were isolated which contained most 5'-nucleotidase but relatively little nucleosidase, whereas rabbit liver lysosomes contain both 5'-nucleotidase and nucleosidase enzymes but little adenyl cyclase.     

Mechanisms of loss of latency of lysosomal enzymes. Effects of incubation on the properties of lysosomal membranes.

1. The effects of sucrose and KCl on the loss of latency of lysosomal enzymes caused by incubation at 37 degrees C, pH 7.4, were examined by using Triton-filled lysosomes from rat liver and two fractions from livers of rats not injected with Triton. 2. After incubation, the percentage free activity of lysosomal enzymes was measured before and after cooling to 0 degrees C in order to determine the amount of latency lost at 37 degrees C without cooling and the additional amount lost on cooling the incubated lysosomes to 0 degrees C. 3. The latency that is lost without cooling is first decreased and then increased by increasing the osmotic strength of the incubation medium with KCl, or with sucrose in the presence of KCl. However, if the osmotic strength is increased with sucrose alone, loss of latency is decreased up to 0.25M-sucrose, but is increased only slightly at higher sucrose concentrations. Apparently the lysosome is permeated by hyperosmolar KCl but not by sucrose during incubation. 4. If the osmotic strength of the assay medium is increased with KCl, the loss of latency caused by incubation for 60 min in hyperosmolar KCl is repressed. Thus it appears that a KCl-permeated lysosome can be obtained which is relatively stable until exposure to lower osmolarities. 5. The loss of latency caused by cooling incubated lysosomes to 0 degrees C is largely eliminated if the osmotic strength of the medium in which the lysosomes are cooled is raised sufficiently with either sucrose or KCl. 6. Osmotic-fragility curves were obtained after incubation for 1 and 60 min at iso-osmoticity (0.2M-KCl or 0.25 M-sucrose). Although little loss of latency occurs at iso-osmoticity, lysosomes incubated for 60 min display greatly increased fragility on exposure to hypo-osmolar KCl, hypo-osmolar sucrose or hyperosmolar KCl. 7. It is suggested that permeability to KCl at 37 degrees C and the increase in fragility on exposure to hypo-osmolar conditions are both consequences of injury, probably from enzymic action, sustained by the lysosomal membrane during incubation at 37 degrees C.     

Structural changes in lysosomes from cultured human fibroblasts in Duchenne's muscular dystrophy

We have previously reported a decreased activity of the lysosomal enzyme dipeptidyl aminopeptidase-I (DAP-I) in cultured fibroblasts from patients with Duchenne's muscular dystrophy (DMD). Here we report that electron microscope examination of these cells reveals the presence of abundant lamellar bodies, a morphologic abnormalities commonly associated with impaired lysosomal function. Morphometric analysis of these cytoplasmic figures in dystrophic cells shows a sevenfold increase relative to normal controls (P less than 0.01). Analysis of lysosomal density profiles by density gradient centrifugation reveals similar patterns in normal and DMD cells. Treatment of lysosomes wit the nonionic detergent Triton X-100 causes an activation of DAP-I. This activation, attributable to structure-linked latency, is markedly diminished in DMD cells which show an optimal activation of only 180% compared to 255% for control fibroblasts (P less than 0.01). These data suggest an alteration in the properties of the lysosomal membrane in DMD fibroblasts. This suggestion is also supported by studies on the release of DAP-I from lysosomes by osmotic shock which show it to be a membrane-associated enzyme with membrane-binding characteristics intermediate between those of tightly bound beta-glucosidase and those of unbound N-acetylgalactosaminidase. The latency characteristics of these other lysosomal enzymes are not altered in the DMD cells, indicating that the effect is specific for DAP-I.     

Influence of insulin on lysosomal activity and urea production in isolated parenchymal cells from rat liver.

Non-latent (free) activities of two lysosomal enzymes (acid phosphatase and beta-glucuronidase) and urea production were measured in purified rat liver parenchymal cells incubated in the presence and absence of insulin. Non-latent enzyme activity was measured by including 0.25M sucrose in the assay mixtures to provide osmotic protection to the lysosomes. Total enzyme activity was estimated with Triton X-100 in the homogenates. Insulin was found to inhibit ureogenesis and to reduce non-latent lysosomal enzyme activity in the hepatocytes in vitro. Our data support the idea that insulin inhibits autophagy in rat liver parenchymal cells. Such an effect of insulin may also explain the inhibitory action of insulin on urea production in the rat liver.     

Effect of solute hydrogen bonding capacity on osmotic stability of lysosomes

The effect of solute hydrogen bonding capacity on the osmotic stability of lysosomes was examined through measurement of free enzyme activity of lysosomes after their incubation in sucrose and poly(ethylene glycol) (PEG) (1500–6000 Da molecular mass) media. Free enzyme activity of the lysosomes was less in the PEG medium than that in the sucrose medium under the same hypotonic condition. The lysosomal enzyme latency loss decreased with increasing hydrogen bonding capacity of the solute. In addition, the lysosomes lost less latency at lower incubation temperature. The results indicate that solute hydrogen bonding capacity plays an important role in the osmotic protection of an incubation medium to lysosomes.     

LYSOSOMAL ENZYMES OF RAT INTESTINAL MUCOSA

Six intracellular hydrolases known to be associated with lysosomes in rat liver were found in rat intestinal mucosa. The extent to which they were particulate-bound and the degree of enzyme release when the particulate fractions were suspended in hypotonic media followed the same pattern in both mucosa and liver. The specific activities of the mucosa enzymes were either comparable to or slightly smaller than those of the liver enzymes. These results suggest that the mucosa hydrolases belong to lysosome-like particles. However, differential fractionation of the mucosa indicated that the particles from the mucosa sediment at lower centrifugal forces than do those from the liver and are more heterogeneous in size, bearing a closer resemblance to kidney lysosomes. Possible physiological functions of particulate-bound digestive enzymes in intestinal mucosa are discussed.     

Studies on bone enzymes. The assay of acid hydrolases and other enzymes in bone tissue.

1. Nine acid hydrolases, cytochrome oxidase, alkaline phenylphosphatase and catalase were demonstrated in 0.25m-sucrose homogenates of newborn-rat calvaria. The acid hydrolases were: acid phenylphosphatase, acid beta-glycerophosphatase, beta-glucuronidase, beta-N-acetylglucosaminidase (beta-N-acetylaminodeoxyglucosidase), acid ribonuclease and acid deoxyribonuclease, showing optimum activity at about pH5; cathepsin, beta-galactosidase and hyaluronidase, with optimum activity at about pH3.6. 2. The main kinetic characters of these enzymes have been studied and methods for their quantitative assay have been worked out. The activities present in bone are given and compared with those found in liver. 3. Acid-phosphatase activity was assayed with phenyl phosphate and beta-glycerophosphate as substrates: activities with these two substrates appeared to be due to two different enzymes. Acid phenylphosphatase is particularly labile and is readily inactivated by various physical or chemical agents.     

Localization of oxidized nocotinamide--adenine dinucleotide glycohydrolase in the mouse liver nuclear envelope.

NAD+ glycohydrolase activity located in the nuclear envelope was maximally solubilized by treatment with 0.1--0.2% Triton X-100. The residual activity largely represents the chromatin-associated NAD+ glycohydrolase. Under these conditions the phospholipids were extensively solubilized (over 90%) while leaving the nuclei physically stable, although the nuclear membranes were removed, as shown by electron microscopy. After Triton X-100 treatment, deoxyribonuclease I did not significantly affect the residual NAD+ glycohydrolase activity, although the DNA was completely broken down. This enzyme activity can be released from the nuclear pellet by incubation with phospholipase C. For comparative studies, the glucose 6-phosphatase activity, known to be present in the nuclear envelope, was investigated. Treatment with 0.01% Triton X-100 released 10--20% of the phospholipids, but without solubilizing either glucose 6-phosphatase or NAD+ glycohydrolase. Higher Triton X-100 concentrations (0.1--1.0%) inhibited glucose 6-phosphatase, but not NAD+ glycohydrolase activity. NAD+ glycohydrolase is apparently present in a latent form in the nuclear envelope. Glucose 6-phosphatase, However, shows no such latency.     

Membranous localization and properties of ATPase of rat liver lysosomes.

Lysosomes isolated from rat liver were found to have ATPase activity (EC No 3.6.1.3). Subfractionation of the lysosomes revealed a membranous localization of ATPase activity. The enzyme has half maximal activity at 0.2 mM ATP and is inhibited by high concentrations of ATP. The apparent Km for divalent metal is 0.2 mM, and either Ca2+ or Mg2+ give maximal activity. The ATPase activity has latency when lysosomes are isolated from rats treated with Triton WR-1339. This latency may be due to the presence of internalized sucrose because the activity of L fraction lysosomes is much less latent and Triton WR-1339 itself is not inhibitory. The latency of glucosaminidase, a marker enzyme for lysosomes, contrasts with the low latency of the ATPase and points to an ATPase with an exposed active site in intact lysosomes.     

Transformation of neutral to alkaline fructose 1,6-bisphosphatase. Converting enzyme activity in the large-particle fraction from rabbit liver

A liver particle fraction containing lysosomes catalyzes the conversion of native rabbit liver fructose 1,6-bisphosphatase (EC 3.1.3.11), having a neutral pH optimum, to a modified form with an alkaline pH optimum. The “converting enzyme” activity is partially recovered with the membranes from disrupted particles, and is also detected in “intact” particles isolated and maintained in isotonic buffered sucrose. The converting enzyme activity associated with the membrane fraction is expressed at pH 6.5, but not at pH 4.5, although activity at the lower pH appears when the enzyme is released from the membranes with Triton X-100. In contrast, proteolytic activity as measured with peptide and protein substrates is maximal at pH 5.0 or below, and is the same for the membrane-bound or solubilized proteases. The results suggest that a specific converting enzyme, at least partially associated with a particle (possibly lysosomal) membrane, is responsible for the modification of fructose bisphosphatase and the change in its catalytic properties.     

Herpes simplex virus and human cytomegalovirus replication in WI-38 cells. III. Cytochemical localization of lysosomal enzymes in infected cells.

Cytochemical localization of the lysosomal enzymes acid phosphatase and arylsulfatase in cells infected by herpes simplex virus (HSV) or human cytomegalovirus (CMV) showed the following interactions between viruses and host cell lysosomes: (i) many enveloped progeny viruses were located within cytoplasmic vacuoles containing lysosomal enzyme activity; (ii) naked cytoplasmic capsids appeared to acquire an envelope by budding directly into lysosomes; and (iii) many of the cytoplasmic dense bodies that are characteristic of CMV-infected cells and are thought to represent noninfectious aggregates of CMV structural proteins (I. Sarov and I. Abady, Virology 66:464-473, 1975) also acquired a limiting membrane by budding into lysosomes. Autophagy of other cytoplasmic elements was not observed, suggesting that there is some specificity involved in the association of viral particles and CMV dense bodies with lysosomes. Despite the presence of potentially destructive hydrolases, there was little evidence of significant morphological damage to intralysosomal viruses, and high titers of infectious particles were released into the medium. It would therefore appear that significant levels of HSV and CMV infectivity normally persist even though many progeny particles are directly exposed to lysosomal enzymes.     

Activity and distribution of bacteriolytic N-acetyl-muramidase during growth of Acanthamoeba castellanii in axenic culture.

Bacteriolytic endo N-acetylmuramidase of Acanthamoeba castellanii has been studied. In amoeba cells the enzyme, like exo N-acetylglucosaminidase and acid phosphatase, is attached to the lysosomes, as it is sedimentable when homogenates are prepared in medium containing sucrose. The sedimentability could be abolished by treatment with Triton X-100, thermal disintegration or by osmotic shock. The sedimentability and acid pH optima of the enzyme are highly characteristic of lysosomes. However, in young cultures over 50 per cent of enzyme activity was secreted by amoeba cells to the environment. The enzyme activity changed with the phase of growth cycle. The activity of enzyme expressed as units per mg of amoeba protein or per constant number of cells has been found to increase over 10 fold on aging of amoeba cultures. The increase in enzyme activity was stopped by actidione. The possible mechanisms of the regulation of the activity of lysosomal enzyme synthesis by amoebae are discussed.     

Assay and subcellular localization of the arylsulphatases in rat brain

—The properties and subcellular localization of type I (nitrophenyl) and type II (nitrocatechol) arylsulphatases were investigated in brain tissue of the rat, and optimal assay conditions were established. Sulphate, phosphate and sulphite ions inhibited the nitrocatechol sulphatases; nitrophenyl sulphatase was inhibited only by sulphite. The presence of latent enzyme activity was demonstrated for the nitrocatechol sulphatases, beta-glucuronidase, and beta-glycerophosphatase in rat and mouse brain homogenates. These hydrolases were highly sensitive to mechanical and osmotic damage; and Triton X-100 was very effective in releasing their latent (bound) activities, a finding suggestive of a lysosomal localization. Activity of nitrophenyl sulphatase was unaffected by osmotic changes or Triton X-100, characteristics suggesting a membranous association for this enzyme. Total activity of nitrophenyl sulphatase was approximately twice as great in canine gray matter as in canine white matter; the converse obtained for beta-glucuronidase activity. Values for total enzymic activity of the nitrocatechol sulphatases in canine white and gray matter were similar. Fractionation of homogenates from rat brain by differential centrifugations and separation of crude mitochondrial fractions by sucrose density gradient centrifugations revealed the following: (1) most of the nitrocatechol sulphatase activity (93 per cent) and all of the nitrophenyl sulphatase activity were sedimentable; (2) crude mitochondrial fractions exhibited the highest relative specific activity (RSA = 1·38) for the nitrocatechol sulphatases, whereas microsomal fractions displayed the highest RSA for nitrophenyl sulphatase (1·89); (3) the lightest fraction (A + B) and the densest fraction (E) from the sucrose density gradient contained most of the activity for both the type I and type II arylsulphatases, whereas the RSA of cytochrome oxidase was greatest in the intermediate density regions (fractions C and D); (4) the highest RSA for beta-glucuronidase and beta-glycerophosphatase occurred in gradient fraction C; (5) appreciable activity of beta-glycerophosphatase was found in a nerve ending fraction (M₃). It is suggested that the hydrolases in heterogeneous tissue like brain might be associated with lysosomal particles of differing enzyme compositions and varying populations, and that the data on distribution lend credence to the concept of bimodal and possible trimodal particle affinity for the hydrolases of brain tissues.