Localization and solubilization of a rat liver microsomal carnitine acetyltransferase.

Carnitine acetyltransferase activity had been previously shown to occur in peroxisomes, mitochondria, and a membranous fraction of rat and pig hepatocytes. When components of this third subcellular fraction (plasma membranes, components of the Golgi apparatus, and microsomes) were further separated, carnitine acetyltransferase fractionated with the microsomes. Microsomes isolated by three different methods (isopycnic sucrose density zonal centrifugation, high-speed differential centrifugation, and aggregation with Ca²⁺ followed by low-speed differential centrifugation) all contained carnitine acetyltransferase activity. The lability of carnitine acetyltransferase in microsomes isolated by different methods and in different isolation media is reported.When total microsomes were subfractionated into rough and smooth components, carnitine acetyltransferase activity was found to the same extent in both and was tightly associated with the microsomal membrane. The microsomal enzyme was rapidly inactivated in 0.25 m sucrose or 0.1 m phosphate, but was stable for at least 2 weeks in 0.4 m KCl. Extensive treatment with high ionic strength salt solutions, 1% Triton X-100, or a combination of the two was used to solubilize microsomal carnitine acetyltransferase activity.Carnitine octanoyltransferase activity was also found in the microsomal fractions isolated by three different methods, but no carnitine palmitoyltransferase was detected in the microsomal fractions. It is proposed that microsomal carnitine acetyl- and octanoyltransferases could be involved in the transfer of acyl groups across the microsomal membrane, thereby providing a source of acetyl and other acyl CoA's at sites of acetylation reactions and synthesis.     

COMPOSITION OF CELLULAR MEMBRANES IN THE PANCREAS OF THE GUINEA PIG : I. Isolation of Membrane Fractions

The subcellular components involved in the synthesis, transport, and discharge of secretory proteins in the guinea pig pancreatic exocrine cell have been isolated from gland homogenates by differential and gradient centrifugation. They include rough and smooth microsomes derived respectively from the rough endoplasmic reticulum and Golgi periphery, a zymogen granule fraction consisting mainly of mature zymogen granules and a smaller population of condensing vacuoles, and a plasmalemmal fraction. Membrane subfractions were obtained from the particulate components by treatment with mild (pH 7.8) alkaline buffers which extract the majority (>95%) of the content of secretory proteins, allowing the membranes to be recovered from the extracting fluid by centrifugation. The purity of the fractions was assessed by electron microscopy and by assaying marker enzymes for cross-contaminants. The rough and smooth microsomes were essentially free of mitochondrial contamination; the smooth microsomes contained <15% rough contaminants. The zymogen granule fraction and its derived membranes were free of rough microsomes and contained <3% contaminant mitochondria. The plasmalemmal fraction was heterogeneous as to origin (deriving from basal, lateral, and apical poles of the cell) and contained varying amounts of adherent fibrillar material arising from the basement membrane and terminal web. The lipid and enzymatic composition of the membrane fractions are described in the following reports.     

Isolation of Golgi fractions from colchicine-treated rat liver. II. Electrophoretic characterization.

1. Intact Golgi fractions, three from colchicine- or ethanol-treated rat livers and two from a control, were analyzed by sodium dodecyl sulfate (SDS) polyacrylamide gel electrophoresis. All the fractions showed very similar electrophoretic profiles with 33 protein bands, some of which, especially albumin, had rather higher density in the secretory vesicle fraction than those in the cisternal fraction. 2. Using albumin as the content marker, the Golgi fractions were subfractionated into membranes and contents by freezing-thawing and sonication followed by centrifugation. Distribution of galactosyltransferase among these membrane preparations showed that this enzyme was more enriched in the Golgi cisternal membranes than in the secretory vesicle membranes. 3. All the membrane preparations from the Golgi complex showed very similar patterns on electrophoresis, which were distinctly different from those of microsomal membranes and of plasma membrane. Furthermore, all the Golgi content subfractions had similar protein components, most of which were also found in serum. The microsomal contents, however, showed a considerably different pattern from those of the Golgi contents. 4. From these results it could be concluded that the secretory vesicles are indeed a member of the Golgi complex despite their different appearance and morphology.     

Subcellular fractionation of Hymenolepis diminuta with special reference to the localization of marker enzymes

A method for subcellular fractionation of Hymenolepis diminuta using whole worm homogenization and differential centrifugation is presented. Different fractions obtained in this study were screened for the presence of enzymes that serve as markers for plasma membrane, brush border, mitochondria, Golgi complex, endoplasmic reticulum, peroxisomes, lysosomes and cytosol. The purity of fractions was also monitored by transmission electron microscopy. The purity of fractions, particularly the brush border membranes, are compared to those obtained by previous methods for H. diminuta or other tissues.     

Studies on mouse liver urate oxidase

Summary Distribution of urate oxidase in subcellular components such as nuclei, mitochondria, lysosomes, microsomes, and cell sap, was investigated by both enzymatic and immunochemical methods. The subcellular components were prepared from mouse liver homogenate by differential centrifugation and the resulting microbody-rich mitochondrial fraction was fractionated by sucrose density gradient centrifugation. The enzymatically determined urate oxidase was distributed mainly in mitochondrial and lysosome fractions. The immunochemically assayed urate oxidase antigen was localized in mitochondrial, lysosome, and microsome fractions. The antigen to enzyme ratio was 1.0 in the mitochondrial and lysosome fractions, and about 2.0 in the microsome fraction.Sucrose density gradient centrifugation of the mitochondrial fraction indicated that the urate oxidase antigen was distributed around three density bands of 1.07, 1.15, and 1.24. The main band (1.24) was consistent with the microbody fraction. From these results, it was suggested that a precursor protein (proenzyme) might be located in the microsome fraction.This work was supported in part by a grant 777007 from the Ministry of Education, Japan, in 1972.     

Analytical study of microsomes and isolated subcellular membranes from rat liver VIII. Subfractionation of preparations enriched with plasma membranes, outer mitochondrial membranes, or Golgi complex membranes

Preparations enriched with plasmalemmal, outer mitochondrial, or Golgi complex membranes from rat liver were subfractionated by isopycnic centrifugation, without or after treatment with digitonin, to establish the subcellular distribution of a variety of enzymes. The typical plasmalemmal enzymes 5'-nucleotidase, alkaline phosphodiesterase I, and alkaline phosphatase were markedly shifted by digitonin toward higher densities in all three preparations. Three glycosyltransferases, highly purified in the Golgi fraction, were moderately shifted by digitonin in both this Golgi complex preparation and the microsomal fraction. The outer mitochondrial membrane marker, monoamine oxidase, was not affected by digitonin in the outer mitochondrial membrane marker, monoamine oxidase, was not affected by digitonin in the out mitochondrial membrane preparation, in agreement wit its behavior in microsomes. With the exception of NADH cytochrome c reductase (which was concentrated in the outer mitochondrial membrane preparation), typical microsomal enzymes (glucose-6-phosphatase, esterase, and NADPH cytochrome c reductase) displayed low specific activities in the three preparations; except for part of the glucose-6-phosphatase activity in the plasma membrane preparation, their density distributions were insensitive to digitonin, as they were in microsomes. The influence of digitonin on equilibrium densities was correlated with its morphological effects. Digitonin induced pseudofenestrations in plasma membranes. In Golgi and outer mitochondrial membrane preparations, a few similarly altered membranes were detected in subfractions enriched with 5'-nucleotidase and alkaline phosphodiesterase I. The alterations of Golgi membranes were less obvious and seemingly restricted to some elements in the Golgi preparation. No morphological modification was detected in digitonin-treated outer mitochondrial membranes. These results indicate that each enzyme is associated with the same membrane entity in all membrane preparations and support the view that there is little overlap in the enzymatic equipment of the various types of cytomembranes.     

Isolation of peroxisomes from the dog kidney cortex.

The present study was undertaken to separate peroxisomes of the dog kidney cortex by the methods of discontinuous sucrose density gradient and zonal centrifugation. The separation of subcellular particles was evaluated by measuring the activities of reference enzymes, beta-glycerophosphatase for lysosomes, succinate dehydrogenase for mitochondria, glucose-6-phosphatase for microsomes, and catalase and D-amino acid oxidase for peroxisomes. The activities of D-amino acid oxidase and catalase were mainly observed in fractions 1 and 2 (1.6 and 1.7 M sucrose) obtained by discontinuous sucrose density-gradient centrifugation. Small amounts of acid phosphatase and succinate dehydrogenase contaminated these fractions. Considerably higher activity of catalase was determined in the supernatant, while D-amino acid oxidase showed a lower activity. By the method of zonal centrifugation, the highest specific activities of catalase and D-amino acid oxidase were found in fraction 50 (1.73 M sucrose) with no succinate dehydrogenase, acid phosphatase or glucose-6-phosphatase activity. These results suggested that peroxisomes of dog kidney cortex were clearly separated in 1.73 M sucrose from mitochondria, lysosomes and microsomes by zonal centrifugation.     

Purification of peroxisomes from livers of normal and clofibrate-treated mice

A method for the isolation of peroxisomes from livers of normal and clofibrate-treated mice is described. The method utilizes glutaraldehyde to stabilize peroxisomal membranes, and isopycnic centrifugation of a light mitochondrial fraction through a linear metrizamide gradient to achieve optimal resolution from other organelles. On the basis of the biochemical and morphological data, the peroxisomal preparations are indicated as of high purity: contamination by mitochondria, lysosomes, and plasma membranes is negligible, and the level of contaminating microsomes is around 5% for normal peroxisomes and 8% for peroxisomes from clofibrate-treated mice. Peroxisomal membranes prepared by carbonate extraction contain two major polypeptides of approximately 70,000 Da, and show 2 and 8% contamination by microsomal membrane protein for the preparations from normal and clofibrate-treated mice, respectively.     

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.     

Glycoprotein synthesis in the adult rat pancreas. IV. Subcellular distribution of membrane glycoproteins

Zymogen granule membranes from the rat exocrine pancreas displays distinctive, simple protein and glycoprotein compositions when compared to other intracellular membranes. The carbohydrate content of zymogen granule membrane protein was 5-10-fold greater than that of membrane fractions isolated from smooth and rough microsomes, mitochondria and a preparation containing plasma membranes, and 50-100-fold greater than the zymogen granule content and the postmicrosomal supernate. The granule membrane glycoprotein contained primarily sialic acid, fucose, mannose, galactose and N-acetylglucosamine. The levels of galactose, fucose and sialic acid increased in membranes in the following order: rough microsomes less than smooth microsomes less than zymogen granules. Membrane polypeptides were analyzed by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The profile of zymogen granule membrane polypeptides was characterized by GP-2, a species with an apparent molecular weight of 74 000. Radioactivity profiles of membranes labeled with [3H]glucosamine or [3H]leucine, as well as periodic acid-Schiff stain profiles, indicated that GP-2 accounted for approx. 40% of the firmly bound granule membrane protein. Low levels of a species similar to GP-2 were detected in membranes of smooth microsomes and the preparation enriched in plasma membranes but not in other subcellular fractions. These results suggest that GP-2 is a biochemical marker for zymogen granules. Membrane glycoproteins of intact zymogen granules were resistant to neuraminidase treatment, while those in isolated granule membranes were readily degraded by neuraminidase. GP-2 of intact granules was not labeled by exposure to galactose oxidase followed by reduction with NaB3H4. In contrast, GP-2 in purified granule membranes was readily labeled by this procedure. Therefore GP-2 appears to be located on the zymogen granule interior.     

Topology of asialoglycoprotein receptor in rat liver subcellular fractions: a ferritin immunoelectron microscopic study

Direct ferritin immunoelectron microscopy was used to visualize the asialoglycoprotein receptor in various rat liver subcellular fractions. The cytoplasmic surfaces of cytoplasmic organelles such as the rough and smooth microsomes, Golgi cisternae and lysosomes showed hardly any ferritin label exception for the slight labeling of secretory granules found mainly in the light Golgi fraction (GF1). Occasionally, however, open membrane sheet structures, smooth vesicular or tubular structures heavily labeled with ferritin, were present in all these subcellular fractions. These structures probably correspond to fragmented sinusoidal or lateral hepatocyte plasma membranes recovered to these subcellular fractions. When the limiting membranes of the secretion granules were partially broken by mechanical force, a number of ferritin particles frequently were seen attached in large clusters to the luminal surface of the membrane, the cytoplasmic surface of the corresponding domain being slightly labeled. These observations are strong evidence that the receptor protein is never translocated vertically throughout the intracellular transport from ER to plasma membrane via Golgi apparatus and from plasma membrane back to trans-Golgi elements and also in lysosomes, always exposing the major antigenic sites to the luminal or extracellular surface and the minor counterparts to the cytoplasmic surface of the membranes. The receptor protein also is suggested to be concentrated in clusters on the luminal surface of secretion granules when they form on the trans-side of the Golgi apparatus.     

A centrifugation study of rat-liver mitochondria, lysosomes and peroxisomes during the perinatal period.

We have investigated the intracellular distribution of several enzymes on homogenates of late foetal, early postnatal and adult rat livers. Homogenates were subjected to differential centrifugations in 0.25 M sucrose and four fractions were isolated which corresponded to the N (nuclear) ML (total mitochondrial) P (microsomal) and S (soluble) fractions of de Duve et al. (1955). In general the age of the animal did not significantly affect the distribution pattern. Reference enzymes of mitochondria, lysosomes and peroxisomes were mainly recovered in the total mitochondrial fraction (ML). Glucose-6-phosphatase and esterase, both located in the endoplasmic reticulum, were chiefly associated with the microsomal fraction P together with galactosyltransferase (a reference enzyme of the Golgi apparatus). 5'-Nucleotidase, (a plasma membrane enzyme) exhibits a bimodal distribution and is mainly recovered in the N and the P fractions. Such results indicate that the membrane composition of the fractions isolated by the fractionation scheme was used, does not appreciably differ for the late foetal, early postnatal and adult rat livers. An analytical fractionation of the mitochondrial (ML) fraction of livers at different stages of development was performed by isopycnic centrifugation in sucrose gradients and in glycogen gradients using sucrose solutions of various concentrations as the solvents. The distribution of mitochondria, lysosomes and peroxisomes were assessed by establishing the distribution of their reference enzymes. Some physical characteristics of the particles were deduced from the manner in which the distributions were influenced by the sucrose concentration of the centrifugation medium. The distribution of liver mitochondrial enzymes one day prenatal differs strikingly from that of enzymes one day postnatal; foetal mitochondria seem characterized by a high osmotic space and a high hydrated matrix density; neonatal mitochondria seem devoid of an osmotic space and the density of their hydrated matrix is markedly lower than that of the foetal mitochondria. As ascertained by the distribution of mitochondrial enzymes in a sucrose 2H2O gradient, the high density of a foetal mitochondria matrix does not mainly originate from a lower amount of hydration water. The behavior of lysosomal enzymes in media with increasing concentrations of sucrose suggests that lysosomes originating from late foetal rat liver are endowed with a very small osmotic space. As for the peroxisomes, our results do not display significant behavior differences in centrifugations that would indicate physicochemical changes of these particles during the perinatal period.     

Sedimentation field flow fractionation of mitochondrial and microsomal membranes from corn roots

Sedimentation field flow fractionation (sed-FFF) is shown to be a valuable procedure for analysis of a wide variety of subcellular particle preparations. The principles underlying this relatively new separation procedure are described. Separation is based on differences between particles in mass and/or density. As in chromatography, the procedure involves relating on-line or off-line measurements made on the effluent from the separation chamber to the elution (retention) time. In this work effluents were monitored for absorbance at 254, 280, and/or 320 nm; collected fractions were assayed for protein content, total ATPase activity, and/or marker enzyme activities and, when appropriate, were examined by electron microscopy. The ratio of the absorbances at 254 and 320 nm was found to provide a sensitive measure of partial resolution of subcellular particles. Preparations containing all of the subcellular particles of corn roots (exclusive of nuclei, cell walls, and ribosomes), and fractions thereof enriched in mitochondria, microsomes, Golgi membranes, or plasma membranes, were examined by sed-FFF. The subcellular particles appear to remain largely intact. All of the particles observed had a mass less than 2 X 10(11) g/mol. All of the preparations were grossly heterogeneous with respect to effective mass distribution. This is due in part to heterogeneity with respect to the organelle of origin. In microsome preparations, components of low, medium, and high density were present in the unretained peak; the retained region had comparatively more high density particles. Plasma membrane preparations had a very wide effective particle mass distribution. The observations suggest that, in addition to its utility for analytic purposes, sed-FFF is likely to prove useful for micro-preparative fractionation of some subcellular particle preparations. Sed-FFF and density gradient centrifugation can be utilized as complementary methods.     

Intracellular localization of N-formyl chemotactic receptor and Mg dependent ATPase in human granulocytes

Human granulocytes were disrupted by nitrogen cavitation and the lysates fractionated by sucrose density gradient centrifugation at 83 000 × g for 20 min (rate zonal) or 3.5 h (isopycnic). The distribution of marker enzymes allowed the identification of the following subcellular components: plasma membrane, Golgi, endoplasmic reticulum, azurophil granules, specific granules, mitochondria and cytosol. Examination of the gradient fractions by electron microscopy confirmed the biochemical marker analysis. The protocol permitted isolation of vesicles highly enriched in either plasma membrane or Golgi (galactosyl transferase) activities. Absolute plasma membrane yields of 40–60% were achieved with a 20–70-fold increase in specific activity of surface marker over the cells. Plasma membrane sedimented to an average density of 1.14 g·cm⁻³. Galactosyl transferase activity was bimodal in distribution. The denser peak cosedimanted with specific granules (g9 = 1.19). The lighter peak sedimented to unique position at an average density of 1.11, was enriched 18-fold over the low speed supernatant, and contained structures resembling Golgi. N-Formyl-Met-Leu-Phe binding and Mg²⁺ -ATPase activities cosedimented with the plasma membrane as well as specific granule and/or high density galactosyl transferase fractions. These findings suggest that Mg²⁺ -ATPase and N-formyl chemotactic peptide receptor activities may be localized in an internal pool of membranes as well as in the plasma membrane and that Golgi may have been a contaminant of previous granulocyte plasma membrane or specific granule preparations.     

Intracellular localization of N-formyl chemotactic receptor and Mg2+ dependent ATPase in human granulocytes

Human granulocytes were disrupted by nitrogen cavitation and the lysates fractionated by sucrose density gradient centrifugation at 83 000 × g for 20 min (rate zonal) or 3.5 h (isopycnic). The distribution of marker enzymes allowed the identification of the following subcellular components: plasma membrane, Golgi, endoplasmic reticulum, azurophil granules, specific granules, mitochondria and cytosol. Examination of the gradient fractions by electron microscopy confirmed the biochemical marker analysis. The protocol permitted isolation of vesicles highly enriched in either plasma membrane or Golgi (galactosyl transferase) activities. Absolute plasma membrane yields of 40–60% were achieved with a 20–70-fold increase in specific activity of surface marker over the cells. Plasma membrane sedimented to an average density of 1.14 g·cm^?3. Galactosyl transferase activity was bimodal in distribution. The denser peak cosedimanted with specific granules (g9 = 1.19). The lighter peak sedimented to unique position at an average density of 1.11, was enriched 18-fold over the low speed supernatant, and contained structures resembling Golgi. N-Formyl-Met-Leu-Phe binding and Mg²⁺ -ATPase activities cosedimented with the plasma membrane as well as specific granule and/or high density galactosyl transferase fractions. These findings suggest that Mg²⁺ -ATPase and N-formyl chemotactic peptide receptor activities may be localized in an internal pool of membranes as well as in the plasma membrane and that Golgi may have been a contaminant of previous granulocyte plasma membrane or specific granule preparations.     

Subcellular fractionation of epithelial cells from toad urinary bladder. 1. Assay of marker enzymes and differential centrifugation

We have undertaken the analytical fractionation of epithelial cells from toad urinary bladder, a tissue extensively used to study epithelial transport of ions and water. In an attempt to establish markers for the main subcellular organelles, a number of enzymes were assayed in cell homogenates. The nearly ubiquitous plasma membrane marker 5'-nucleotidase, and the transferases that donate N-acetylglucosaminyl, galactosyl, and sialyl residues to glycoproteins and glycolipids in the Golgi complex were not detectable. Glucose-6-phosphatase activity was low in relation to that of nonspecific phosphatases and, therefore, not suitable for identifying the endoplasmic reticulum. Like the cytosolic enzyme lactate, dehydrogenase, catalase was essentially found in the high-speed supernatant, with a noteworthy part of aminopeptidase (substrate, leucyl-beta-naphthylamide) and NAD glycohydrolase. Other enzymes, including cytochrome c oxidase, acid phosphatase, acid N-acetyl-beta-glucosaminidase, alkaline phosphatase, alkaline phosphodiesterase I, nucleoside diphosphatase (substrate ADP), oligomycin-resistant Mg++-ATPase, and mannosyltransferase (acceptor, dolichylphosphate) were fairly active and largely sedimentable. After differential centrifugation, cytochrome oxidase, acid phosphatase, and acid N-acetyl-beta-glucosaminidase were typically associated with the large granule fraction, whereas the other sedimentable enzymes exhibited a broad distribution profile overlapping the nuclear, large granule, and microsome fractions. Their behavior in density equilibrium centrifugation is examined in a companion paper.     

Glycoprotein synthesis in the adult rat pancreas: IV. Subcellular distribution of membrane glycoproteins

Zymogen granule membranes from the rat exocrine pancreas displays distinctive, simple protein and glycoprotein compositions when compared to other intracellular membranes. The carbohydrate content of zymogen granule membrane protein was 5–10-fold greater than that of membrane fractions isolated from smooth and rough microsomes, mitochondria and a preparation containing plasma membranes, and 50–100-fold greater than the zymogen granule content and the postmicrosomal supernate. The granule membrane glycoprotein contained primarily sialic acid, fucose, mannose, galactose and $\text{N-}\text{acetylglucosamine}$. The levels of galactose, fucose and sialic acid increased in membranes in the following order: rough microsomes < smooth microsomes < zymogen granules.Membrane polypeptides were analyzed by polyacrylamide gel electrophoresis in sodium dodecyl sulfate. The profile of zymogen granule membrane polypeptide was characterized by GP-2, a species with an apparent molecular weight of 74 000. Radioactivity profiles of membranes labeled with [³H]glucosamine or [³H]leucine, as well as periodic acid-Schiff stain profiles, indicated that GP-2 accounted for approx. 40% of the firmly bound granule membrane protein. Low levels of a species similar to GP-2 were detected in membranes of smooth microsomes and the preparation enriched in plasma membranes but not in other subcellular fractions. These results suggest that GP-2 is a biochemical marker for zymogen granules.Membrane glycoproteins of intact zymogen granules were resistant to neuraminidase treatment, while those in isolated granule membranes were readily degraded by neuraminidase. GP-2 of intact granules was not labeled by exposure to galactose oxidase followed by reduction with NaB³H₄. In contrast, GP-2 in purified granule membranes was readily labeled by this procedure. Therefore GP-2 appears to be located on the zymogen granule interior.     

Glycoprotein synthesis in the adult rat pancreas: II. Characterization of Golgi-rich fractions

Golgi-rich fractions were prepared from homogenates of adult rat pancreas by discontinuous gradient centrifugation. These fractions were characterized by stacks of cisternae associated with large, irregular vesicles and were relatively free of rough microsomes, mitochondria, and zymogen granules. The Golgi-rich fractions contained 50% of the UDP-galactose: glycoprotein galactosyltransferase activity; the specific activity was 12-fold greater than the homogenate. Such fractions represented < 19% of thiamine pyrophosphatase, uridine diphosphatase, adenosine diphosphatase, and Mg²⁺-adenosine triphosphatase. Zymogen granules and the Golgi-rich fractions were extracted with 0.2 m NaHCO3, pH 8.2, and the membranes were isolated by centrifugation. The glycoprotein galactosyltransferase could not be detected in granule membranes, while the specific activity in Golgi membranes was 25-fold greater than the homogenate.At least 35 polypeptide species were detected in Golgi membranes by polyacrylamide gel electrophoresis in 1% sodium dodecylsulfate. These ranged in molecular weight from 12,000 to <160,000. There were only minor differences between Golgi membranes and smooth microsomal membrane. In contrast, zymogen granule membranes contained fewer polypeptides. A major polypeptide, which represented 30–40% of the granule membrane profile, accounted for less than 3% of the polypeptides of Golgi membranes or smooth microsomal membranes.     

Characterization of a secretory vesicle-rich fraction from lactating bovine mammary gland.

Fractions enriched in secretory vesicles were obtained from lactating bovine mammary tissue by a straightforward procedure involving gentle homogenization and centrifugation in isotonic milk salt solution containing Ficoll. Secretory vesicle-rich fractions could also be obtained from lactating rat mammary gland by this procedure. With rats, yields of vesicles were substantially increased by administration of colchicine or thioglucose to animals several hours before sacrifice. Isolated fractions were enriched in lactose and consisted predominantly of 0.2–1.2 μm diameter vesicles, many of which contained casein micelles. Enzymatic, compositional and morphological examination revealed vesicle preparations to be largely free of contamination by rough endoplasmic reticulum, mitochondria, nuclei, peroxisomes and lysosomes. Specific activity of several marker enzymes of the secretory vesicle fraction were similar to, or intermediate between, Golgi apparatus and milk lipid globule membranes. Amounts of cholesterol and gangliosides in vesicle fractions approached levels found in plasma membranes. In distribution of major phospholipids, secretory vesicles were intermediate between Golgi apparatus and milk lipid globule membranes. The pattern of polypeptides of secretory vesicle membrane was qualitatively similar to that of Golgi apparatus membranes. While there were similarities between these polypeptide patterns and that of lipid globule membranes, the latter contained relatively more of certain polypeptides, particularly the internal coat-associated polypeptides of the globule membrane. These observations are discussed in relation to the endomembrane hypothesis and the origin of the membrane of milk lipid globules.