The egasyn gene affects the processing of oligosaccharides of lysosomal beta-glucuronidase in liver.

The accumulation of the relatively large amounts of beta-glucuronidase in microsomal fractions of normal mice depends on formation of complexes with the protein egasyn. Unexpectedly, it was found that the egasyn gene also affects the processing of beta-glucuronidase, which is segregated to lysosomes. In egasyn-positive mice lysosomal beta-glucuronidase from liver has a mean pI of 5.9 with a minor proportion at pI 5.4, whereas in egasyn-negative mice the proportion of the two lysosomal forms is reversed. Combined experiments measuring susceptibility to neuraminidase and to endoglycosidase H and specific binding to Ricinus communis lectin-agarose columns showed that the alterations in isoelectric point were associated with a decrease in complex oligosaccharides of lysosomal beta-glucuronidase in egasyn-positive mice. Since this alteration occurs not only in a congenic strain carrying the Eg0 gene but also in several other inbred strains that are homozygous for this gene, it is considered to be a genuine effect of the Eg gene rather than other genes that might regulate oligosaccharide processing. Also, the alteration is likely to be a result of direct physical interaction of the egasyn protein and lysosomal beta-glucuronidase, since a second lysosomal enzyme, beta-galactosidase, which does not form complexes with egasyn, is unaffected. The results suggest a model in which egasyn not only causes accumulation of beta-glucuronidase in the microsomal compartment but also acts upon the precursor to lysosomal beta-glucuronidase to alter its interaction with trans-Golgi-apparatus processing enzymes.     

Relationships between levels of membrane-bound glucuronidase and the associated protein egasyn in mouse tissues

Mouse beta-glucuronidase has a dual intracellular localization, being present in both endoplasmic reticulum and lysosomes of several tissues. Previous studies demonstrated that the protein egasyn is complexed with microsomal but not lysosomal glucuronidase and that a mutant lacking egasyn is deficient in microsomal, but not lysosomal, glucuronidase. By means of a recently developed radioimmunoassay for egasyn, the relationship between microsomal glucuronidase levels and egasyn levels has been examined in various adult tissues, during postnatal development in liver, and after androgen induction of glucuronidase in kidney. The results indicate that the relative availability of egasyn determines the balance between glucuronidase incorporation into membranes and that into lysosomes.     

Involvement of the carboxyl-terminal propeptide of beta-glucuronidase in its compartmentalization within the endoplasmic reticulum as determined by a synthetic peptide approach

The proenzyme form of beta-glucuronidase is compartmentalized in large quantities within the endoplasmic reticulum by binding to the esterase, egasyn. Also, the propeptide of the proenzyme form of beta-glucuronidase is likely located at the carboxyl terminus. We have, therefore, tested if this carboxyl-terminal peptide is important in binding to egasyn. A polyclonal antibody to a 30-mer synthetic peptide, corresponding to the carboxyl-terminal 30 amino acids of pro-beta-glucuronidase, provided evidence that egasyn binds to the carboxyl terminus of beta-glucuronidase. This antibody interacted with proenzyme beta-glucuronidase-egasyn complexes in which one, two, or three egasyn molecules were bound to the beta-glucuronidase tetramer, but not with those complexes (M4) which contained four egasyn molecules. We interpret these results as indicating that all available carboxyl termini of the beta-glucuronidase proenzyme tetramer are shielded by egasyn in the M4 complexes. The same antibody did not recognize the mature lysosomal form of beta-glucuronidase, indicating that only the proenzyme form of microsomal beta-glucuronidase contains the original carboxyl terminus. Also, the synthetic 30-mer was found to be a specific and potent inhibitor (50% inhibition at 1.3 microM) of the esterase activity of purified egasyn but exhibited little inhibitory activity toward other purified esterases including a rat trifluoroacetylated esterase or egasyn esterase from another species. Together, these data describe a potent interaction of the exposed carboxyl terminus of precursor glucuronidase with the esterase catalytic site of egasyn, which in turn results in the specific localization of glucuronidase within the lumen of the endoplasmic reticulum.     

Purification and chemical properities of mouse liver lysosomal (L form) beta-glucuronidase.

The lysosomal form (L form) of beta-glucuronidase was purified 6,500-fold from the liver of C57BL/6J mice with high yield. Purified enzyme was homogeneous as judged by polyacrylamide gel electrophoresis in the presence or absence of sodium dodetcyl sulfate. The microsomal forms of beta-glucuronidase were spontaneously converted to the L form. The purified L form is a tetramer of molecular weight of 280,000 to 300,000, composedd of four identical subunits of 75,000 molecular weight. The enzyme contains a high content of arginine and glutamic acid and a very low content of sulfur-containing amino acids. Approximately 7% of the enzyme molecule is compose of carbohydrate. Sugars in the L form are glucosamine, mannose, galactose, and glucose. Sialic acid and fucose are absent in the enzyme.     

Egasyn, a protein which determines the subcellular distribution of beta-glucuronidase, has esterase activity

The glycoprotein egasyn complexes with and stabilizes precursor beta-glucuronidase in microsomes of several mouse organs. Several observations indicate egasyn is, in addition, an esterase. Liver homogenates of egasyn-positive strains have specific electrophoretically separable esterases which are absent in egasyn-negative mice. These esterases react with anti-egasyn serum. A specific esterase was likewise complexed with immunopurified microsomal beta-glucuronidase. The esterases were, like egasyn and microsomal beta-glucuronidase, concentrated in the microsomal subcellular fraction. Egasyn which is not bound to beta-glucuronidase, which represents 80-90% of total liver egasyn, is not complexed with other liver proteins. Egasyn, therefore, specifically stabilizes beta-glucuronidase in microsomes. The esterase activity is inhibited by bis-p-nitrophenyl phosphate indicating it is a carboxyl esterase. Several possible functions of egasyn-esterase activity are discussed.     

An accessory protein identical to mouse egasyn is complexed with rat microsomal beta-glucuronidase and is identical to rat esterase-3

We report biochemical, immunological, and genetic studies which demonstrate that an accessory protein with the essential features of mouse egasyn is complexed with and stabilizes a portion of beta-glucuronidase in microsomes of rat liver. The accessory protein exists as a complex with beta-glucuronidase since it coprecipitates with beta-glucuronidase after treatment of extracts with a specific beta-glucuronidase antibody. The two proteins are associated by noncovalent bonds since they are easily dissociated at elevated temperatures. Only 20-25% of total liver accessory protein is complexed with microsomal beta-glucuronidase. The remainder exists as a free form. The molecular weight of the accessory protein is 61 to 63 kDa depending upon the rat strain of origin. This protein, like mouse egasyn, has esterase catalytic activity and is concentrated in microsomes. The accessory protein is genetically polymorphic with at least four alleles. Combined biochemical and genetic evidence indicates it is identical with esterase-3 of the rat. Also, both mouse egasyn and rat esterase-3 react with antisera to egasyn and to rat esterase-3, indicating they are homologous proteins. Several inbred rat strains lack microsomal beta-glucuronidase. The same strains lack the accessory protein, suggesting that stabilization of beta-glucuronidase in rat microsomes requires egasyn.     

Inheritance in mice of the membrane anchor protein egasyn: The Eg locus determines egasyn levels

Previous studies have suggested that the binding of mouse glucuronidase to endoplasmic reticulum membrane is stabilized by the membrane protein egasyn. Using a radioimmunoassay for egasyn, we have now examined the inheritance of egasyn levels in mice. Mice of the ibred strain C57BL/6J, which have normal levels of microsomal glucuronidase, contained 56±10 g egasyn per gram of liver. Mice of the inbred strain YBR, which carry the Eg ⁰ mutation resulting in the absence of microsomal glucuronidase, did not contain detectable levels of egasyn. The F₁ progeny of these two strains contained intermediate levels of egasyn, 25±4 g egasyn per gram of liver. Progeny from the backcross of these F₁ animals to YBR were distributed equally into two discrete phenotypic classes. One class lacked both egasyn and microsomal glucuronidase, while the other class contained 25±3 g egasyn per gram of liver and contained normal levels of microsomal glucuronidase. Thus egasyn levels are determined by the Eg locus and show additive inheritance. These results suggest that the Eg gene codes for egasyn and that it is the inability to produce egasyn that results in a deficiency of microsomal glucuronidase in the Eg ⁰ mutant.This work was supported in part by USPHS Grant GM-19521.     

beta-Glucuronidase is transported slowly to lysosomes in BW5147 mouse lymphoma cells: evidence that the prelysosomal enzyme is not restricted to the endoplasmic reticulum

The post-translational processing of beta-glucuronidase in BW5147 mouse lymphoma cells is slow relative to other newly synthesized lysosomal enzymes. To characterize this slow maturation the acid hydrolase was immunoprecipitated from cells pulse-labeled with [2-3H]mannose. Radiolabeled beta-glucuronidase migrated as the precursor form of the enzyme for up to 4 h of chase, whereas another acid hydrolase, beta-galactosidase, was processed completely to its mature form within this same time period. Both beta-glucuronidase and beta-galactosidase obtained high levels of mannose 6-phosphate (Man 6-P) within 60 min of their biosynthesis. The Man 6-P content of beta-galactosidase declined rapidly during a subsequent chase while that of beta-glucuronidase remained high during the first 4 h of chase and then slowly declined. 3H-Labeled phosphorylated high mannose-type oligosaccharides isolated from beta-glucuronidase after 1 h of chase were composed primarily of species with one or two phosphodiester groups, but oligosaccharides with one and two phosphomonoesters became the predominant phosphorylated species with longer chase times. The phosphorylated oligosaccharides attached to other newly synthesized acid hydrolases, on the other hand, contained primarily phosphodiester species at all chase times. When BW5147 cells were pulsed with [3H]mannose and chased in the presence of monensin to disrupt transport, the number of phosphorylated oligosaccharides recovered from beta-glucuronidase was comparable to the quantity recovered from the enzyme produced by non-drug-treated cells. The number of phosphorylated units recovered from all other newly synthesized acid hydrolases, however, was greater in the presence of the ionophore than in its absence. Nondenaturing gel electrophoresis studies indicated that beta-glucuronidase existed in two forms at steady state within BW5147 cells and, as such, was similar to liver beta-glucuronidase in which a large percentage of the enzyme was present as a complex bound to egasyn. These data suggest that newly synthesized beta-glucuronidase produced by BW5147 cells complexes with an egasyn-like protein within the endoplasmic reticulum. This interaction retards the enzyme's migration through the secretory apparatus but does not prevent its access to Golgi-associated processing enzymes.     

The effect of TEPC-183 plasmacytoma growth on beta-glucuronidase activity in serum and tissues of tumor-bearing mice

beta-Glucuronidase activity increased in the serum of BALB/c mice during the growth of the IgM-secreting plasmacytoma, TEPC-183. The increase appeared to correlate with tumor burden. The beta-glucuronidase activity in tissue homogenates of spleen, liver, and kidney from tumor-bearing mice also increased significantly compared to the levels found in corresponding tissues from normal control mice. Assays of lysosomal and microsomal fractions from livers of TEPC-bearing mice indicated that approximately 70% of the enzyme activity was associated with the lysosomal fraction and the remainder with the microsomal fraction. A similar distribution was found in homogenates prepared from the plasmacytoma itself. In contrast to this the beta-glucuronidase activity in livers from normal BALB/c mice is nearly equally distributed between lysosomal and microsomal fractions.     

Lumenal location of the microsomal beta-glucuronidase-egasyn complex

Mouse liver beta-glucuronidase is stabilized within microsomal vesicles by complexation with the accessory protein egasyn. The location of the beta-glucuronidase-egasyn complex and free egasyn within microsomal vesicles was investigated. Surprisingly, it was found that neither the complex nor free egasyn are intrinsic membrane components. Rather, both are either free within the vesicle lumen or only weakly bound to the inside of the vesicle membrane. This conclusion was derived from release studies using low concentrations of Triton X-100 or controlled sonication. Both the intact complex and free egasyn were released in parallel with lumenal proteins, not with intrinsic membrane components. Also, beta-glucuronidase was protected from digestion by proteinase K by the membrane of microsomal vesicles. The hydrophilic nature of both the complex and free egasyn was confirmed by phase separation experiments with the detergent Triton X-114. Egasyn is one of an unusual group of esterases that, despite being located within the lumen or only weakly bound to the lumenal surface of the endoplasmic reticulum, do not enter the secretory pathway.     

Involvement of the esterase active site of egasyn in compartmentalization of beta-glucuronidase within the endoplasmic reticulum

Organophosphorous compounds, which are potent inhibitors of egasyn-esterase activity, caused a rapid dissociation of the high molecular weight egasyn-microsomal beta-glucuronidase complex when administered in vivo or when added in vitro to microsomal suspensions. The dissociation was relatively specific to phosphodiester inhibitors of the esterase active site. Also, the egasyn-esterase active site was inaccessible to substrates and to inhibitors when egasyn was complexed to beta-glucuronidase. Dissociation of the egasyn-microsomal beta-glucuronidase complex in vivo by organophosphorous compounds was followed by massive and rapid secretion of microsomal beta-glucuronidase, but not egasyn, into plasma. These experiments implicate the egasyn-esterase active site in attachment of microsomal beta-glucuronidase to egasyn by a novel mechanism that, in turn, compartmentalizes beta-glucuronidase within the endoplasmic reticulum.     

Rabbit β-glucuronidase. Subcellular distribution and immunochemical properties

1. The subcellular distribution of beta-glucuronidase and other hydrolases in rabbit liver was investigated. beta-Glucuronidase was found in both microsomal and lysosomal fractions. 2. Multiple forms of beta-glucuronidase were present in extracts of microsomal and lysosomal fractions. All forms were common to both fractions. 3. A specific antiserum against beta-glucuronidase was raised, and characterized by immunoprecipitation and affinity-chromatography procedures. 4. The immunological identity of the multiple forms in the pure beta-glucuronidase preparation, and the immunological identity of the beta-glucuronidase complement of lysosomal extracts with that of microsomal extracts, were demonstrated by means of the antiserum. The presence of inactive enzyme in various enzyme preparations was shown.     

Intracellular transport of mouse kidney β-glucuronidase induced by gonadotrophin

1. The response of renal beta-glucuronidase with time to the injection of gonadotrophin was investigated in each submicrosomal fraction of rough and smooth microsomal fractions of mouse kidney homogenate. 2. The increase in beta-glucuronidase activity appeared initially in membranes of the rough microsomal fraction, 24h after injection. 3. Afterwards the newly synthesized enzyme appeared in the contents of the rough microsomal fraction and was subsequently found in the smooth microsomal fraction, reaching a maximum concentration in this fraction at 72h. 4. At this juncture, a decrease in the enzyme activity was observed in rough microsomal contents whereas the lysosomal fraction had reached its maximum value. 5. The time-course of the appearance of beta-glucuronidase in the submicrosomal fractions after the gonadotrophin stimulation suggests that the newly synthesized enzyme at the site of membrane-bound ribosomes is transferred across the membrane into cisternae of the rough endoplasmic reticulum, and then is transported into lysosomes via the smooth endoplasmic reticulum. 6. The properties of microsomal and lysosomal beta-glucuronidases were compared.     

Effects of ammonia on processing and secretion of precursor and mature lysosomal enzyme from macrophages of normal and pale ear mice: evidence for two distinct pathways

Lysosomal enzymes have been shown to be synthesized as microsomal precursors, which are processed to mature enzymes located in lysosomes. We examined the effect of ammonium chloride on the intracellular processing and secretion of two lysosomal enzymes, beta-glucuronidase and beta-galactosidase, in mouse macrophages. This lysosomotropic drug caused extensive secretion of both precursor and mature enzyme forms within a few hours, as documented by pulse radiolabeling and molecular weight analysis. The normal intracellular route for processing and secretion of precursor enzyme was altered in treated cells. A small percentage of each precursor was delivered to the lysosomal organelle slowly. Most precursor forms traversed the Golgi apparatus, underwent further processing of carbohydrate moieties, and were then secreted in a manner similar to secretory proteins. The lag time for secretion of newly synthesized beta-galactosidase precursor was notably longer than that for the beta-glucuronidase precursor. The source of the secreted mature enzyme was the lysosomal organelle. Macrophages from the pale ear mutant were markedly deficient in secretion of mature lysosomal enzyme but secreted precursor forms normally. These results suggest that ammonia-treated macrophages contain two distinct intracellular pathways for secretion of lysosomal enzymes and that a specific block in the release of lysosomal contents occurs in the pale ear mutant.     

Biosynthesis of rat liver pI-6.1 esterase, a carboxylesterase of the cisternal space of the endoplasmic reticulum.

Biosynthesis of the rat liver microsomal esterase with pI 6.1 was investigated in cell-free systems and in cultured hepatocytes, by using a rabbit antiserum. Protein synthesis directed by total rat liver RNA in wheatgerm extract or reticulocyte lysate generated a single immunoprecipitable product, also found with the RNA extracted from bound, but not from free, polysomes. When dog pancreas microsomal fractions were included, reticulocyte lysates gave two processed products, a prominent one slightly larger, and another slightly smaller, than the precursor, both resistant to exogenous proteinases and, hence, segregated within vesicles. The processing was co-translational; it consisted of the removal of a peptide fragment and, for the large component, the addition of a single oligosaccharide chain. Indeed, this component bound to concanavalin A-Sepharose and gave the small one (approximately 2000 Mr loss) by cleavage with endo-beta-N-acetylglucosaminidase H (endo-H). A single labelled peptide was precipitated from hepatocytes incubated with [35S]methionine. Its apparent Mr was decreased by approximately 2000 after treatment with endo-H; it was then identical with that of an unglycosylated form produced in hepatocytes poisoned with tunicamycin. Even in that case, immunoreactive peptides were not detected in the culture medium. Whether synthesized in reticulocyte lysate or in hepatocytes, the glycosylated forms migrated in SDS/polyacrylamide-gel electrophoresis as the purified enzyme labelled with [3H]di-isopropyl fluorophosphate. Thus, although pI-6.1 esterase is not secreted, its biosynthesis is, as yet, indistinguishable from that of secretory proteins. Its oligosaccharide moiety is apparently not the structural element that retains it in the endoplasmic reticulum.     

Purification and characterization of microsomal and lysosomal beta-glucuronidase from rat liver by use of immunoaffinity chromatography.

Rat liver beta-glucuronidase (EC 3.2.1.31), both from microsomal and lysosomal fractions, were purified about 9500-fold over the homogenate with high yield using affinity chromatography prepared by coupling purified specific immunoglobulin G against rat preputial gland beta-glucuronidase to Sepharose 2B and isoelectric focusing. The purified enzymes appeared homogeneous on electrophoresis in polyacrylamide gel and had a molecular weight of approximately 310000. In dodecylsulfate polyacrylamide gel electrophoresis, the microsomal beta-glucuronidase showed a single band corresponding to a molecular weight of 79000, while the lysosomal beta-glucuronidase had three distinct bands which consisted of one major and two minor bands corresponding to molecular weight of 79000, 74000, and 70000, respectively. A broad pH activity curve with a single optimum at pH 4.4 was observed in both the microsomal and the lysosomal beta-glucuronidases. Immunological gel diffusion technique with rabbit antiserum against rat liver lysosomal beta-glucuronidase revealed that both enzymes had the same or quite similar antigenic determinants.     

Purification and characterization of rat liver microsomal beta-glucuronidase.

Beta-Glucuronidase (EC 3.2.1.31) has been isolated from rat-liver microsomes by a novel chromatographic method employing antibody to rat preputial gland beta-glucuronidase coupled to Sepharose. The purified enzyme, homogeneous by several methods, was purified some 1700-fold. The microsomal beta-glucuronidase has been characterized with respect to catalysis, stability, and molecular weight. The purified enzyme is a tetramer of 290 000 daltons. Comparative studies with lysosomal beta-glucuronidase indicate that while these two enzymes are electrophoretically distinct, they are catalytically and immunologically identical and have indistinguishable molecular dimensions. The results suggest that microsomal and lysosomal beta-glucuronidase are charge isomers.     

Effect of potassium deficiency on mouse kidney lysosomal enzymes.

Mice of inbred strains A/J, C57BL/6J and C57BL/6J beige were kept on a K+-deficient diet for up to 40 days to determine the magnitude and mechanism of changes in tissue lysosomal enzymes. From days 10 to 40 glucuronidase activity increased 3-fold in kidney of K+-deficient mice, but there was little effect on beta-galactosidase or acid phosphatase activity. Similar increases in kidney glucuronidase activity occurred in inbred strains known to have genetically altered control of the synthesis (A/J) and secretion (C57BL/6J beige) of glucuronidase in kidney proximal-tubule cells. Deprivation of K+ did not affect glucuronidase activity in liver, spleen, lung and brain, but there was a 2-3-FOld increase in glucuronidase activity in heart in the C57BL/6J and C57BL/6J beige strains. As shown by specific antibody titration, increased glucuronidase activity in kidney of K+-deficient mice was accompanied by accumulation of enzyme molecules. Likewise in kidney of deficient mice there was an increased rate of synthesis of glucuronidase as measured by incorporation of labelled leucine into immunoprecipitable glucuronidase. In kidney of K+-deficient mice the elevated glucuronidase activity was found in both collecting-tubule and interstitial cells of the medulla. It is probable therefore that a significant fraction of the increased kidney lysosomal synthesis and enzyme activity is due to infiltrating cells.     

Lysosomal Dysfunctions Associated with Mutations at Mouse Pigment Genes

Melanosomes and lysosomes share several structural and biosynthetic properties. Therefore, a large number of mouse pigment mutants were tested to determine whether genes affecting melanosome structure of function might also affect the lysosome. Among 31 mouse pigment mutants, six had 1.5- to 2.5-fold increased concentrations of kidney beta-glucuronidase. Three mutants, pale ear, pearl and pallid, had a generalized effect on lysosomal enzymes since there were coordinate increases in kidney beta-galactosidase and alpha-mannosidase. The effects of these three mutations are lysosome specific since rates of kidney protein synthesis and activities of three nonlysosomal kidney enzymes were normal. Also, the mutants are relatively tissue specific in that all had normal liver lysosomal enzyme concentrations.--A common dysfunction in all three mutants was a lowered rate of lysosomal enzyme secretion from kidney into urine. While normal C57BL/6J mice daily secreted 27 to 30% of total kidney beta-glucuronidase and beta-galactosidase, secretion of these two enzymes was coordinately depressed to 1 to 2%, 8 to 9% and 4 to 5% of total kidney enzyme in the pale-ear, pearl and pallid mutants, respectively. Although depressed lysosomal enzyme secretion is the major pigment mutant alteration, the higher lysomal enzyme concentrations in pearl and pallid may be partly due to an increase in lysosomal enzyme synthesis. In these mutants kidney glucuronidase synthetic rate was increased 1.4- to 1.5-fold.--These results suggest that there are several critical genes in mammals that control the biogenesis, processing and/or function of related classes of subcellular organelles. The mechanism of action of these genes is amenable to further analysis since they have been incorporated into congenic inbred strains of mice.     

Intracellular transport and processing of lysosomal cathepsin B

Intracellular transport and processing of lysosomal cathepsin B was investigated in the subcellular fractions of rat liver by pulse-labeling experiments with [35S]methionine in vivo. A newly synthesized procathepsin B with a molecular weight of 39 kDa firstly appeared in the rough microsomal fraction at 10 min postinjection of label. This procathepsin B moved from the microsomal fractions to the Golgi subfractions at 30 min postinjection, and then a processed mature enzyme appeared in the lysosomal fraction at 60 min. These results suggest that the propeptide-processing of procathepsin B takes place in lysosomes in the course of intracellular transport from endoplasmic reticulum through Golgi complex to lysosomes.