Perparation and comparative analytical study of cat liver microsomes]

Cat liver homogenates have been fractionated by differential centrifugation. Four particulate fractions (1 000 X g, 10 000 X g, and 145 000 X g) and a supernatant have been obtained. The biochemical composition of these fractions has been established from the assay and distribution pattern of 22 enzymatic and chemical constituents including marker enzymes for mitochondria, lysosomes, peroxisomes, plasma membranes, endoplasmic reticulum, Golgi apparatus and cell sap. The microsomal fraction was characterized by a moderate contamination with large cytoplasmic granules and by a low yield in protein and cholesterol. It contained 50 per cent of Golgi complex and about 40 per cent of plasma membranes. Morphological analysis of subcellular fractions was performed and confirmed biochemical results.     

Analytical study of microsomes and isolated subcellular membranes from rat liver. VII. Distribution of protein-bound sialic acid

Detailed investigations by quantitative centrifugal fractionation were conducted to determine the subcellular distribution of protein-bound sialic acid in rat liver. Homogenates obtained from perfused livers were fractionated by differential centrifugation into nuclear fraction, large granules, microsomes, and final supernate fraction, or were used to isolate membrane preparations enriched in either plasma membranes or Golgi complex elements. Large granule fractions, microsome fractions, and plasma membrane preparations were subfractionated by density equilibration in linear gradients of sucrose. In some experiments, microsomes or plasma membrane preparations were treated with digitonin before isopycnic centrifugation to better distinguish subcellular elements related to the plasma membrane or the Golgi complex from the other cell components; in other experiments, large granule fractions were obtained from Triton WR-1339-loaded livers, which effectively resolve lysosomes from mitochondria and peroxisomes in density gradient analysis. Protein-bound sialic acid and marker enzymes were assayed in the various subcellular fractions. The distributions obtained show that sialoglycoprotein is restricted to some particular domains of the cell, which include the plasma membrane, phagolysosomes, and possibly the Golgi complex. Although sialoglycoprotein is largely recovered in the microsome fraction, it has not been detected in the endoplasmic reticulum-derived elements of this subcellular fraction. In addition, it has not been detected either in mitochondria or in peroxisomes. Because the sialyltransferase activities are associated with the Golgi complex, the cytoplasm appears compartmentalized into components which biogenetically involve the Golgi apparatus and components which do not.     

Immunoelectron microscope localization of cytochrome P-450 on microsomes and other membrane structures of rat hepatocytes

Localization of cytochrome P-450 on various membrane fractions of rat liver cells was studied by direct immunoelectron microscopy using ferritin-conjugated antibody to the cytochrome. The outer surfaces of almost all the microsomal vesicles were labeled with ferritin particles. The distribution of the particles on each microsomal vesicle was usually heterogeneous, indicating clustering of the cytochrome, and phenobarbital treatment markedly increased the labeled regions of the microsomal membranes. The outer nuclear envelopes were also labeled with ferritin particles, while on the surface of other membrane structures such as Golgi complexes, outer mitochondrial membranes and plasma membranes the labeling was scanty and at the control level. The present observation indicates that cytochrome P-450 molecules are localized exclusively on endoplasmic reticulum membranes and outer nuclear envelopes where they are probably distributed not uniformly but heterogeneously, forming clusters or patches. The physiological significance of such microheterogeneity in the distribution of the cytochrome on endoplasmic reticulum membranes is discussed.     

Secretory carrier membrane proteins 31-35 define a common protein composition among secretory carrier membranes.

A novel compositional overlap between membranes of exocrine and endocrine granules, synaptic vesicles, and a liver Golgi fraction has been identified using a monoclonal antibody (SG7C12) raised against parotid secretion granule membranes. This antibody binds secretory carrier membrane proteins with apparent Mr 31,000, 33,000 and 35,000 (designated SCAMPs 31, 33, 35). The proteins are nonglycosylated integral membrane components, and the epitope recognized by SG7C12 is on the cytoplasmic side of the granule membrane. SCAMP 33 is found in all secretory carrier membranes studied so far while SCAMP 35 is found in exocrine and certain endocrine granules and liver Golgi membranes and SCAMP31 only in exocrine granules. They are not related to other similar-sized proteins that have been studied previously in relation to vesicular transport and secretion. Immunocytochemical staining shows that these SCAMPs are highly concentrated in the apical cytoplasm of exocrine cells. Antigens are present not only on exocrine granules and synaptic vesicles but also on other smooth membrane vesicles of exocrine and neural origin as revealed by immunolocalization in subcellular fractions and immunoadsorption to antibody-coated magnetic beads. The wide tissue distribution and localization to secretory carriers and related membranes suggest that SCAMPs 31-35 may be essential components in vesicle-mediated transport/secretion.     

Localization of 5′-nucleotidase activity in the parotid acinar cells of a rat treated with isoproterenol

Summary Cytochemical localization of 5- nucleotidase (AMPase) has been investigated in the parotid acinar cells of rats at various stages of exocytic secretion induced by an administration of isoproterenol (IPR).In the resting stage, the acinar cells show AMPase activity located on the baso-lateral and luminal plasmalemma, and in the earliest secretory stage the luminal plasma membranes are devoid of the enzymatic activity. However, these particular regions exhibit AMPase activity during the advanced stages of secretion, and the AMPase positive membranes become absorbed into the cytoplasm by endocytic activity. The absorbed membrane components then seem to be degraded by the action of lysosomes.The intracellular fate of the endocytic vacuoles has been examined by the aid of ferritin particles introduced retrogradely through ductal lumina. Ferritin containing vacuoles are distributed in the cytoplasm, and these droplets change into secondary lysosomes. No tracer particles are recognized in the internal space of the Golgi lamella and its associated vesicles.The results suggested that in the exocytic secretion of parotid acinar cells, AMPase originating from plasma membrane intermingles with the membranes derived from secretion granules, and is translocated into cytoplasm by an endocytic mechanism. The internalized membrane components are, at least partly, degraded by lysosome action.     

Distribution of the integral membrane protein NADH-cytochrome b5 reductase in rat liver cells, studied with a quantitative radioimmunoblotting assay.

The intracellular localization of the post-translationally inserted integral membrane protein, NADH-cytochrome b5 reductase, was investigated, using a quantitative radioimmunoblotting method to determine its concentration in rat liver subcellular fractions. Subcellular fractions enriched in rough or smooth microsomes, Golgi, lysosomes, plasma membrane and mitochondrial inner or outer membranes were characterized by marker enzyme analysis and electron microscopy. Reductase levels were determined both with the NADH-cytochrome c reductase activity assay, and by radioimmunoblotting, and the results of the two methods were compared. When measured as antigen, the reductase was relatively less concentrated in microsomal subfractions, and more concentrated in fractions containing outer mitochondrial membranes, lysosomes and plasma membrane than when measured as enzyme activity. Rough and smooth microsomes had 4-5-fold lower concentrations, on a phospholipid basis than did mitochondrial outer membranes. Fractions containing Golgi, lysosomes and plasma membrane had approximately 14-, approximately 16, and approximately 9-fold lower concentrations of antigen than did mitochondrial outer membranes, respectively, and much of the antigen in these fractions could be accounted for by cross-contamination. No enzyme activity or antigen was detected in mitochondrial inner membranes. Our results indicate that the enzyme activity data do not precisely reflect the true enzyme localization, and show an extremely uneven distribution of reductase among different cellular membranes.     

Nonaprenyl-4-hydroxybenzoate transferase, an enzyme involved in ubiquinone biosynthesis, in the endoplasmic reticulum-Golgi system of rat liver

The properties and distribution of nonaprenyl-4-hydroxybenzoate transferase in rat liver were investigated with subcellular fractions, liver perfusion, and in vivo labeling with [3H]solanesyl-PP. In addition to some ubiquinone-9, only one labeled intermediate, i.e. nonaprenyl-4-hydroxybenzoate, was obtained. In the total microsomal fraction, the enzyme had a pH optimum of 7.5 and was completely inhibited by Triton X-100 and deoxycholate, but not by taurodeoxycholate and beta-octyl glucoside. Liver, kidney, and spleen demonstrated the highest activities of nonaprenyl-4-hydroxybenzoate transferase. Upon subcellular fractionation, high specific activities were found in smooth II microsomes and Golgi III vesicles. The enzyme was also found in lysosomes and plasma membranes, but only at low levels in rough and smooth I microsomes and mitochondria and not at all in peroxisomes and cytosol. When the product of the transferase reaction was used as a substrate in vitro and in a perfusion system, the only product obtained was end product ubiquinone-9. Although the transferase reaction was associated with the inner, luminal surface of microsomal vesicles, the terminal reaction(s) for ubiquinone-9 synthesis are found at the outer cytoplasmic surface. The results suggest that the major site for ubiquinone synthesis is the endoplasmic reticulum-Golgi system, which also participates in the distribution of ubiquinone-9 to other cellular membranes.     

Immunocytochemical localization of class I H-2 histocompatibility antigens of mouse liver

The subcellular location of class I H-2 histocompatibility antigens was determined for mouse liver using immunocytochemical techniques and correlated with information determined by cell fractionation and analysis in situ. Surface antigens first were localized by standard procedures involving surface labeling with ferritin-labeled antibody. This approach could not be used for internal membranes either in situ or in fractions since the antigens are not expressed at the cytoplasmic surface. For this purpose, thin sections of tissues embedded in Lowicryl were analyzed and quantitated. The in situ analysis confirmed the presence of H-2 antigens on internal membrane compartments as well as on the cell surface and helped rule out the possibility that distributions based on analyses by immunoprecipitation of fractions of internal membranes were influenced greatly by plasma membrane contamination. Quantitation was provided by immunoprecipitation of H-2 antigens from radioiodinated or metabolically labeled isolated and highly purified cell fractions. The findings establish the presence of class I H-2 histocompatibility antigens in endoplasmic reticulum, Golgi apparatus and plasma membrane in the approximate ratios of 1:3:7. No class I H-2 histocompatibility antigens could be detected in mitochondria, salt extracts of isolated membranes or NP-40-insoluble membrane material.     

Subcellular distribution of rat liver porin

The subcellular distribution of rat liver porin was investigated using the immunoblotting technique and monospecific antisera against the protein isolated from the outer membrane of rat liver mitochondria. Subfractionation of mitochondria into inner membranes, outer membranes and matrix fractions revealed the presence of porin only in the outer membranes. Porin was also not detected in highly purified subcellular fractions, including plasma membranes, nuclear membranes, Golgi I and Golgi II, microsomes and lysosomes. Thus, liver porin is located exclusively in the outer mitochondrial membrane.     

Is cytochrome P-450 transported from the endoplasmic reticulum to the Golgi apparatus in rat hepatocytes?

The Golgi apparatus mediates intracellular transport of not only secretory and lysosomal proteins but also membrane proteins. As a typical marker membrane protein for endoplasmic reticulum (ER) of rat hepatocytes, we have selected phenobarbital (PB)-inducible cytochrome P- 450 (P-450[PB]) and investigated whether P-450(PB) is transported to the Golgi apparatus or not by combining biochemical and quantitative ferritin immunoelectron microscopic techniques. We found that P-450(PB) was not detectable on the membrane of Golgi cisternae either when P-450 was maximally induced by phenobarbital treatment or when P-450 content in the microsomes rapidly decreased after cessation of the treatment. The P-450 detected biochemically in the Golgi subcellular fraction can be explained by the contamination of the microsomal vesicles derived from fragmented ER membranes to the Golgi fraction. We conclude that when the transfer vesicles are formed by budding on the transitional elements of ER, P-450 is completely excluded from such regions and is not transported to the Golgi apparatus, and only the membrane proteins destined for the Golgi apparatus, plasma membranes, or lysosomes are selectively collected and transported.     

Endocytosis in secretory cells

Membranes of secretion granules inserted during exocytosis into the luminal plasma membranes of glandular cells are retrieved by endocytosis as revealed by electron dense tracers applied selectively to the apical cell surfaces. Two major pathways that endocytic vesicles may take are described: (1) a direct route to the Golgi complex (e.g. in parotid and exocrine pancreas) with later appearance of the tracer in the periphery of mature secretion granules; (2) an indirect route with lysosomes as a first station and the subsequent appearance of tracer in stacked Golgi cisternae. It is presumed that some of the retrieved membrane follows the same pathways and is reutilized in the secretory cycle.     

Subcellular localization of the enzyme that forms mannosyl retinyl phosphate from guanosine diphosphate [14C]mannose and retinyl phosphate.

The subcellular distribution of the enzyme catalysing the conversion of retinyl phosphate and GDP-[14C]mannose into [14C]mannosyl retinyl phosphate was determined by using subcellular fractions of rat liver. Purity of fractions, as determined by marker enzymes, was 80% or better. The amount of mannosyl retinyl phosphate formed (pmol/min per mg of protein) for each fraction was: rough endoplasmic reticulum 0.48 +/- 0.09 (mean +/- S.D.); smooth membranes (consisting of 60% smooth endoplasmic reticulum and 40% Golgi apparatus), 0.18 +/- 0.03; Golgi apparatus, 0.13 +/- 0.03; and plasma membrane 0.02.     

Membrane retrieval in epithelial cells of isolated thyroid follicles.

Follicles from rat and pig thyroid glands were isolated by digestion with collagenase. The epithelial cells of isolated follicles maintain their structural and functional polarity as shown by incorporation of 3H-leucine and autoradiography. To trace the fate of surface membrane, isolated follicles were opened, stimulated with thyrotropin and incubated for various time intervals with cationized ferritin (CF), uncharged dextran, native ferritin (NF), and latex spheres (0.5 mum in diameter) which were either pre-coated with CF or added together with CF. Uncharged dextran and native ferritin did not bind to the luminal cell membrane, were taken up in small amounts and accumulated in lysosomes; anionic NF was not found in Golgi cisternae in contrast to uncharged dextran which occassionally reached a few Golgi stacks. CF bound rapidly and in clusters to the luminal plasmalemma, preferentially to coated pits, was taken up by endocytosis, accumulated in lysosomes after 5 min and reached the Golgi cisternae after 30 min. Latex spheres were taken up by engulfment through fusion of microvilli and reached the lysosomes. CF particles coating the latex spheres may detach at this station and reach the Golgi cisternae. The findings show that the route of small tracers depends on the charge of the tracer, in agreement with results obtained by Farquhar [8]. Vesicles carrying NF can be traced to lysosomes only, whereas vesicles containing uncharged dextran or - more conspicuously -CF also fuse with Golgi membranes. Large tracers (latex beads) reach only the lysosomes, but CF taken up with them may move to Golgi cisternae.     

Localization of fucosyl residues in cellular compartments of rat duodenal absorptive enterocytes and goblet cells

We have determined the subcellular distribution of fucosyl residues in rat duodenal absorptive enterocytes and goblet cells, using the binding affinity of the lectin I of Ulex europaeus (UEA I). In absorptive enterocytes, UEA I-lectin gold complexes were detected at the brush border and at the basolateral plasma membrane; pits of the plasma membrane were labeled, as were small vesicles, multivesicular bodies, lysosomes, and the Golgi apparatus. In the Golgi stacks, about half of the cisternae showed gold marker particles: accessible fucosyl residues were sparse in the cis subcompartment, the cismost cisterna mostly remaining negative; more intense label was found in medial cisternae; reactions were concentrated in the trans and transmost Golgi subcompartments. Cisternae, tubules and vesicles located at the trans Golgi side were the most constantly and intensely stained Golgi elements. In goblet cells, mucin granules and trans Golgi cisternae were labeled. Rarely, UEA I-gold bound to cisternae of the medial subcompartment; the cis subcompartment remained unstained. In part, UEA I-gold particles were restricted to dilated portions of the transmost Golgi cisterna and to secretory granules.     

Compartmentalization of intracellular membrane glycocomponents is revealed by fracture-label

We used thin-section fracture-label to determine the distribution of wheat-germ agglutinin binding sites in intracellular membranes of secretory and nonsecretory rat tissues as well as in human leukocytes. In all cases, analysis of the distribution of wheat germ agglutinin led to the definition of two endomembrane compartments: one, characterized by absence of the label, includes the membranes of mitochondria and peroxisomes as well as those of the endoplasmic reticulum and nuclear envelope; the other, strongly labeled, comprises the membrane of lysosomes, phagocytic vacuoles, and secretory granules, as well as the plasma membrane. The Golgi apparatus was weakly labeled in all studied tissues.     

Quantitative subcellular study of apical pole membranes from chicken oxyntic cells in resting and HCl secretory state

Vertebrate oxyntic cells, responsible for gastric HCl production, undergo a remarkable morphological reorganization in relation to their secretory cycle. In resting state, the luminal surface of the cells is smooth; a peculiar system of endocellular membranes, the tubular system, occupies the luminal cytoplasm. Actin filaments frame a cortical network between the tubular system and the luminal plasma membrane. With the onset of HCl secretion, the tubular system becomes incorporated into the luminal plasma membrane. Villous processes containing microfilaments fill the secretory surface. This morphological reorganization of membranes and cytoskeletal matrix could regulate HCl secretion by translocation of membranes containing the proton pump from the endocellular compartment to the secretory surface. In this paper, we describe the isolation of membranes that selectively belong to the tubular system or to the cytoplasmic processes of the secretory surface of chicken oxyntic cells. Chicken oxyntic cells are the main cellular component of the proventricular glands. A resting state was obtained after cimetidine treatment, whereas the HCl- secretory state was induced by histamine. We present a comparative analysis of resting and stimulated chicken gastric glands by quantitative subcellular fractionation. The HCl secretory state was related to specific modifications in membrane fractions derived from the secretory pole of oxyntic cells. Morphological and functional reorganization of oxyntic cells was closely correlated with changes in: the sedimentation pattern of the marker enzyme of the apical pole membrane (K-NPPase), the total activity of K-NPPase and nonmitochondrial Mg-ATPase, the valinomycin dependence of K-ATPase, and polypeptides that cosediment in purified membrane fractions. Changes in the distribution pattern of K-NPPase after fractionation of histamine- stimulated glands were consistent with the replacement of the small vesicles typical of resting glands by dense membrane profiles, analogous to the luminal processes of stimulated oxyntic cells. SDS- PAGE showed that, in purified membrane fractions of stimulated glands, the concentration of 28-, 43-, and 200-kD polypeptides increased while that of 95- and 250-kD polypeptides decreased. The present results define the tubular system of oxyntic cells as an organelle with properties different from those of endoplasmic reticulum, mitochondria, and plasma membrane. The biochemical and physico-chemical properties of this membraneous system changed when the organization of the membranes and the cytoskeletal matrix of the apical pole was modified by the onset of HCl secretion.     

Distribution of organelles and membranes between hepatocytes and nonhepatocytes in the rat liver parenchyma. A stereological study

When biochemical studies on the liver are interpreted, the cells of the sinusoidal area frequently receive little attention because, compared to hepatocytes, their contribution to subcellular fractions is assumed insignificant. A systematic stereological analysis of liver parenchyma was therefore performed in order to determine the distribution of organelles and membranes between hepatocytic and nonhepatocytic cells, namely endothelial, Kupffer, and fat-storing cells. The livers were fixed by vascular perfusion and the data were corrected for systematic errors dur to section thickness and compression. The extracellular space compartment includes the lumina of sinusoids (10.6%), the space of Disse (4.9%), and the bile canaliculi (0.4%). Hepatocytes constitute 78% of parenchymal volume; the nonhepatocytes account for 6.3% and consist of 2.8% endothelial cells, 2.1% Kupffer cells, and 1.4% fat- storing cells. The nonhepatocytes contribute 55% of the volume of lipid droplets in the liver, 43% of the lysosomes, and 1.2% of the mitochondria. Although the nonhepatocytes account for only 8% of the total surface area of parenchymal membranes, they contain 26.5% of all the plasma membranes, 32.4% of the lysosomal membranes, 15.1% of the Golgi apparatus 6.4% of the endoplasmic reticulum, and 2.4% of the mitochondrial membranes. The data demonstrate the extent to which nonhepatocytic organelles can potentially contaminate subcellular fractions used for biochemical studies. Particularly important for the interpretation of studies on lysosomes, plasma membrane, and Golgi apparatus is the finding that an appreciable part of these organelles may be derived from cell types other than hepatocytes.     

Intracellular transport of a newly synthesized asialoglycoprotein receptor in rat liver

Intracellular transport of a newly synthesized asialoglycoprotein receptor was studied biochemically using a monospecific antibody for the receptor. Pulse-labeling by intravenous injection of [3H]leucine and pulse-chasing after 10 min by cycloheximide injection resulted in the maximal labeling of the receptor in the rough microsomes at 15 min, in the smooth microsomes and the heavy Golgi subfraction (GF3) at 25 min and in the intermediate plus light Golgi subfraction (GF1+2) at 30 min. By 60 min, the labeling in GF1+2 had decreased and leveled off. In the plasma membrane fraction, the labeled receptor first appeared at 20 min, increased rapidly and also reached a constant level at 40-60 min. Intracellular movement of the newly synthesized receptor in the GF1+2 and plasma membrane fractions was also investigated by purifying the receptor protein from the GF1+2 and plasma membrane fractions by affinity chromatography. It was revealed that the specific radioactivities of the receptor in the two fractions become equilibrated after 60-120 min. The receptor of the various membrane fractions was also pulse-labeled in vivo for 20 min simultaneously with [3H]glucosamine and [14C]leucine, and pulse-chased for the following 40 min. After pulse-labeling for 20 min, the ratio of the radioactivity of [3H]glucosamine or [3H]sialic acid to [14C]leucine of the receptor from the rough and smooth microsomes, and GF3, GF2, and GF1 increased in that order. That of the receptor from the plasma membrane fraction was infinitely higher, because, while a significant amount of 3H-radioactivity was incorporated into the receptor in the Golgi apparatus, only a negligible amount of 14C-radioactivity was incorporated into the same receptor in the plasma membrane due to the delay in the arrival of [14C]leucine labeled receptor to the plasma membrane. After chasing for 40 min, however, the same radioactivity ratios of the GF1 and plasma membrane fractions approached each other. All these results strongly suggest that the distribution of the newly synthesized receptor becomes rapidly equilibrated between the trans-Golgi components and plasma membranes probably by repeated recycling of the receptor protein between the two membranes.     

Monoclonal antibody to a common antigen of secretory granule membranes: intracellular localization and recycling of the antigen after secretion.

Monoclonal antibody (MAb) 170-5 was generated to the secretory granule membrane of rat parotid acinar cells. The MAb recognized integral membrane glycoproteins (SG 170 antigen) localized on the luminal side of the secretory granules with N-linked carbohydrates, molecular weights 92, 84, 76, 69, and 65 KD. Immunohistochemical studies indicated that the SG 170 antigen was found in the secretory granules of both exocrine and endocrine cells and in the lysosomes of various cells in the rat. Immunoelectron microscopy with immunogold revealed that the antigen was present on the membrane of the secretory granules, lysosomes, the Golgi vesicles, and condensing vacuoles in pancreatic and parotid acinar cells and in AR42J rat pancreatic tumor cells; the Golgi stacks exhibited no immunoreaction. The common localization of the antigen in the secretory granule membranes indicated that this antigen may play an essential role in regulated secretion. Employing HRP-labeled MAb 170-5, we followed the retrieval of the antigen after exocytosis in AR42J cells. The MAb was internalized specifically with antigen-mediated endocytosis. It was transported to endosomes, subsequently to the trans-Golgi network, and then packaged into secretory granules. However, the Golgi stacks revealed no uptake of the labeled antibody.     

Phosphomannosyl-enzyme receptors in rat liver. Subcellular distribution and role in intracellular transport of lysosomal enzymes

beta-Hexosaminidase B purified from human fibroblast secretions was used as a ligand to study phosphomannosyl-enzyme receptors in membranes from rat tissues. Enzyme binding to rat liver membranes was saturable, competitively inhibited by mannose 6-phosphate, not dependent on calcium, and destroyed by prior treatment of the hexosaminidase with either alkaline phosphatase or endoglycosidase H. Most (90%) of the phosphomannosyl-enzyme receptors were found in endoplasmic reticulum, Golgi apparatus, and lysosomes; 9.5% in the plasma membrane, and less than 1% in nuclei and mitochondria. Receptors were vesicle-enclosed in all fractions except plasma membrane. Receptors in the endoplasmic reticulum apparently were occupied by endogenous ligands, but most receptors in lysosomes and plasma membrane were unoccupied. Most of the endogenous beta-hexosaminidase was in lysosomes and was released from vesicles by detergent treatment. Displacement of the residual receptor-bound endogenous beta-hexosaminidase (mostly in endoplasmic reticulum and Golgi apparatus) from detergent-treated membranes by mannose 6-phosphate released high uptake enzyme with properties expected for phosphomannosyl-enzymes. Mannose 6-phosphate-inhibitable enzyme receptor activity was found in nine rat organs and correlated roughly with their lysosomal enzyme content. These data support a general model for lysosomal enzyme transport in which the phosphomannosyl-enzyme receptor acts as a vehicle for delivery of newly synthesized acid hydrolases from the endoplasmic reticulum to lysosomes.