Phospholipid and enzyme arrangements of rat liver rough microsomal subfractions from control and methylcholanthrene-treated animals

Rough microsomes from rat liver of both control and methylcholanthrene-treated animals were subfractionated on a discontinuous sucrose gradient into three fractions according the their sedimentation velocity. The slowly sedimenting vesicles were enriched in electron transport enzymes, while those in the pellet showed higher phosphatase and ATPase activities. Methylcholanthrene treatment introduced typical changes in enzyme composition, mainly an increase of the cytochrome P-448. The individual phospholipids exhibited an identical distribution pattern in the three subfractions and no change occurred after induction with methylcholanthrene treatment. Nearest neighbour analysis of phosphatidylethanolamine with dinitrodifluorobenzene revealed a similar pattern in the enzymatically different subfraction, that is, no cross-linking with phosphatidylserine occurred. One-third of the phosphatidylethanolamine was in monomer and dimer form and about two-thirds was protein linked. When membrane and enzyme synthesis was induced, cross-linking to proteins were substantially decreased. The experiments indicate that the phospholipids are distributed in a homogenous fashion in the lateral plane of the rough microsomal membrane and do not support the possibility that phosphatidylethanolamine is specifically associated with cytochrome P-450.     

A calmodulin-stimulated Ca2+ pump in rat aorta plasma membranes

An ATP-driven Ca2+-transport system has been characterized in a microsomal fraction from rat aorta. Calmodulin enhanced 2.5-fold 45Ca accumulation by EGTA-treated microsomes incubated with 10 microM Ca2+ (in the absence of oxalate) by increasing markedly the apparent affinity of the transport system for Ca2+. The ionophore A23187 induced a rapid release of the sequestered 45Ca. The vesicles that took up 45Ca were distributed like plasmalemmal marker enzymes when the microsomal fraction was subfractionated by density gradient centrifugation. In particular, these vesicles were markedly shifted towards higher equilibrium densities after addition to the microsomes of 0.2 mg digitonin/mg protein before isopycnic centrifugation. We conclude that the calmodulin-stimulated Ca2+ pump associated with the microsomal fraction is located in plasmalemmal elements.     

Localization of intracellular triacylglycerol and cholesteryl ester transfer activity in rat tissues

A triacylglycerol and cholesteryl ester transfer activity has been isolated from rat liver. After homogenization, the liver cells were subfractionated into the 10 000 X g pellet, microsomal fraction and postmicrosomal supernatant. Most of the transfer activity appeared to be associated with the microsomal fraction. Rough and smooth microsomes contained nearly equal transfer activities. When isolated microsomes were subject to proteolytic attack, the transfer activity was not inactivated, unless it had been released from the microsomes prior to proteolytic treatment. This indicates that the activity is probably located within the microsomal vesicles. Similar transfer activities were found in the intestinal mucosa of rats, whereas little or no activity was detected in the brain, heart, kidney, or plasma.     

Localization of enzymes in specialized regions of the microsomal membrane.

Microsomal vesicles were centrifuged through sucrose density gradients containing deoxycholate. With 0.15% detergent electron transport enzymes and phosphatases could be separated. Increasing the deoxycholate concentration to 0.19% resulted in separation of the microsomal material into five bands containing (in order from the top of the gradient) adenosine monophosphatase, inosine diphosphatase and some glucose-6-phosphatase (band 1); NADH-linked (band 2) and NADH-linked (band 3) electron transport enzymes; and glucose-6-phosphatase (bands 4 and 5). It appears that enzymes are arranged in specialized patches in the microsomal membrane.     

Biogenesis of endoplasmic reticulum transport vesicles transferring gastric apomucin from ER to Golgi.

Rough endoplasmic reticulum (RER) transport vesicles were generated from gastric mucous cell RER microsomes in the presence of labeled precursors of phospholipids. The vesicles contained 7-10% of their proteins in the form of apomucin (cargo), and 80% of de novo synthesized phosphatidylcholine (PC) was incorporated into the vesicular membrane. In the absence of choline and ethanolamine precursors or in the presence of 3 mM N-ethylmaleimide (NEM), an inhibitor of CTP:phosphocholine cytidylyltransferase, formation of the transport vesicles, their enrichment in the newly synthesized PC, and the total synthesis of PC decreased by 86%, whereas in the presence of 3 mM Zn2+, complete blockage of vesicle formation and PC synthesis was observed. Analysis of the mucin-transporting vesicles indicated that the CTP:phosphocholine cytidylyltransferase and 1,2-diacyl-sn-glycerol:CDP-choline phosphotransferase remained associated with transport vesicles released from ER. The enzymes and other proteins separated from the vesicle surface prior to vesicle fusion with Golgi and the process was induced by phosphorylation. Based on the results of this study, it is proposed that the formation of the ER transport vesicles of gastric mucosal cells is in concert with synthesis of phospholipids and thus in part is regulated by phospholipid-synthesizing enzymes that reside on the membrane during its biogenesis and dissociate from its surface once the task is completed.     

Biogenesis of endoplasmic reticulum membrane in rat liver cells. III. Biosynthesis of NADPH-cytochrome c reductase and cytochrome b5 by loosely-bound ribosomes.

Membrane-bound ribosomes were separated into two distinct classes (loosely-bound and tightly-bound ribosomes) by treatment with 0.6 M KCl, 1 mM puromycin, 0.05% DOC, or 10 mM EDTA. It was also confirmed that any one of these reagents except for EDTA dissociated the same class of ribosomes from the membrane. A population of lighter microsomal vesicles was formed from rough microsomes upon the dissociation of loosely-bound ribosomes by treatment with these chemicals. Rough microsomes were subfractionated into lighter and heavier fractions, L-rMs and H-rMs, by centrifugation using a discontinuous gradient of sucrose consisting of 1.3 M, 1.5 M, and 2.1 M solutions. It was found that L-rMs was rich in loosely-bound ribosomes, whereas H-rMs contained a high proportion of tightly-bound ribosomes. It is likely that loosely-bound and tightly-bound ribosomes are heterogeneously distributed among rough microsomal vesicles. Loosely-bound ribosomes and tightly-bound ribosomes synthesize different kinds of proteins. Two microsomal membrane proteins, NADPH-cytochrome c reductase and cytochrome b5, were exclusively synthesized by loosely-bound ribosomes, whereas serum albumin, which is a major component of the secretory proteins of hepatocytes, was synthesized only by tightly-bound ribosomes. Since the nascent peptides of NADPH-cytochrome c reductase and cytochrome b5 are released from bound ribosomes to the cytoplasmic surface of endoplasmic reticulum, while those of secretory proteins are discharged into the lumen across the membrane, the strength of the association between ribosomes and microsomal membrane seems to be correlated with the direction of release of nascent peptides.     

SELECTIVE RELEASE OF CONTENT FROM MICROSOMAL VESICLES WITHOUT MEMBRANE DISASSEMBLY : I. Permeability Changes Induced by Low Detergent Concentrations

Rat liver rough microsomes treated with a series of desoxycholate (DOC) concentrations from 0.003 to 0.4% were analyzed by isopycnic sucrose density gradient centrifugation in media containing high or low salt concentrations. Tritium-labeled precursors administered in vivo were used as markers for ribosomes (orotic acid, 40 h), phospholipids (choline, 4 h), membrane proteins (leucine, 3 days), and completed secretory proteins of the vesicular cavity (leucine, 30 min). Within a narrow range of DOC concentrations (0.025–0.05%), the vesicular polypeptides were selectively released from the microsomes, while ribosomes, nascent polypeptides, and microsomal enzymes of the electron transport systems were unaffected. The detergent concentration which led to leakage of content was a function of the ionic strength and of the microsome concentration. At the lowest effective DOC concentration the microsomal membranes became reversibly permeable to macromoles as shown by changes in the density of the vesicles in Dextran gradients and by the extent of proteolysis by added proteases. Incubation of rough microsomes with proteases in the presence of 0.025% DOC also led to digestion of proteins from both faces of the microsomal membranes and to a lighter isopycnic density of the membrane vesicles.     

BIOGENESIS OF ENDOPLASMIC RETICULUM MEMBRANES : II. Synthesis of Constitutive Microsomal Enzymes in Developing Rat Hepatocyte

The constitutive enzymes of microsomal membranes were investigated during a period of rapid ER development (from 3 days before to 8 days after birth) in rat hepatocytes. The activities studied (electron transport enzymes and phosphatases) appear at different times and increase at different rates. The increase in the enzyme activities tested was inhibited by Actinomycin D and puromycin. G-6-Pase and NADPH-cytochrome c reductase activities appeared first in the rough microsomes, and subsequently in smooth microsomes, eventually reaching a uniform concentration as in adult liver. The evidence suggests that the enzymes are synthesized in the rough part, then transferred to the smooth part, of the ER. Changes in the fat supplement of the maternal diet brought about changes in the fatty acid composition of microsomal phospholipids but did not influence the enzymic pattern of the suckling. Microsomes from 8-day-old and adult rats lose 95% of PLP and 80% of NADH-cytochrome c reductase activity after acetone-H₂O (10:1) extraction. However, one-half the original activity could be regained by adding back phospholipid micelles prepared from purified phospholipid, or from lipid extracts of heart mitochondria, or of liver microsomes of 8-day or adult rats, thus demonstrating an activation of the enzyme by nonspecific phospholipid. The results suggest that during development the enzymic pattern is not influenced by the fatty acid or phospholipid composition of ER membranes.     

CERAMIDE-GALACTOSYLTRANSFERASE AND CEREBROSIDE-SULPHOTRANSFERASE LOCALISATION IN GOLGI MEMBRANES ISOLATED BY A CONTINUOUS SUCROSE GRADIENT OF MOUSE BRAIN MICROSOMES

Abstract— A 17,000 g supernatant of mouse brain microsomes was subfractionated on a continuous sucrose gradient in order to localise ceramide galactosyltransferase (CGalt, EC 2.4.1.47) and cerebroside sulphotransferase (CST, EC 2.8.2.11), both enzymes involved in the synthesis of myelin lipids. The submicrosomal fractions were analysed for marker enzymes of myelin, plasma membranes, Golgi membranes, endoplasmic reticulum and lysosomes, and their protein distribution was studied. The results and EM studies give evidence that CGalT and CST are located in the Golgi membranes of the brain.     

Biogenesis of the mitochondrial matrix enzyme, glutamate dehydrogenase, in rat liver cells. II. Significance of binding of glutamate dehydrogenase to microsomal membrane

1. Glutamate dehydrogenase and malate dehydrogenase solubilized from liver microsomes were able to rebind to microsomal vesicles while the corresponding dehydrogenases extracted from mitochondria showed no affinity for microsomes. 2. Competition was noticed between microsomal glutamate dehydrogenase and microsomal malate dehydrogenase in the binding to microsomal membranes. Mitochondrial malate dehydrogenase or bovine serum albumin did not inhibit the binding of microsomal glutamate dehydrogenase to microsomes. 3. Binding of microsomal glutamate dehydrogenase to microsomal membranes decreased when microsomes was preincubated with trypsin. 4. Rough microsomal glutamate dehydrogenase was more efficiently bound to rough microsomes than smooth microsomes. Conversely, smooth microsomal glutamate dehydrogenase had higher affinity for smooth microsomes than for rough microsomes. 5. A difference was noticed among the glutamate dehydrogenase isolated from rough and smooth microsomes, and from mitochondria, which suggested the possibility of minor post-translational modification of enzyme molecules in the transport from the site of synthesis to mitochondria.     

Preparation and characterization of total, rough and smooth microsomes from the lung of control and methylcholanthrene-treated rats.

Optimal conditions for the preparation of relatively pure microsomes and microsomal subfractions from rat lung have been determined. The most importnat of these conditions is homogenization of a 20% (w/v) suspension of lung tissue in 0.44 M sucrose/1% (w/v) bovine serum albumin with four up-and-down strokes at 440 rev./min in a Potter-Elvehjem homogenizer. The 10000 X g supernatant prepared from this homogenate can be centrifuged at 105000 X g to obtain total microsomes or subfractionated into rough and smooth microsomes on a Cs+-containing discontinuous sucrose gradient. The total, rough and smooth microsomes have been characterized in terms of their chemical composition, enzymatic activity, and morphology. These preparations should prove useful in studies of various enzymes in lung (e.g. benzpyrene monooxygenase, epoxide hydrase, enzymes of phospholipid and ascorbic acid synthesis) and in subfractionations designed to reveal heterogeneites in the lateral plane of the lung endoplasmic reticulum.     

Localization of enzymes in specialized regions of the microsomal membrane

Microsomal vesicle were centrifuged through sucrose density gradients containing deoxycholate. With 0.15% detergent electron transport enzymes and phosphatases could be separated. Increasing the deoxycholate concentration to 0.19% resulted in separation of the microsomal material into five bands containing (in order from the top of the gradient) adenosine monophosphatase, inosine diphosphatase and some glucose-6-phosphatase (band 1); NADH-linked (band 2) and NADPH-linked (band 3) electron transport enzymes; and glucose-6-phosphatase (bands 4 and 5). It appears that enzymes are arranged in specialized patchers in the microsomal membrane.     

SUBFRACTIONATION OF SMOOTH MICROSOMES FROM RAT LIVER

Total smooth microsomes from rat liver isolated on a Cs⁺-containing sucrose gradient were concentrated and subsequently fractionated by zone centrifugation on a stabilizing sucrose gradient. The prerequisite for fractionation is to prepare total smooth microsomes in a nonaggregated condition, as well as to utilize a procedure which counteracts enzyme inactivation. The median equilibrium density of the various smooth microsomal vesicles ranges from 1.10 to 1.18. The phospholipid/protein ratio is identical in all subfractions, but cholesterol, on a PLP basis, is enriched in the subfractions with the highest sedimentation velocity. The enzyme distribution pattern reveals a pronounced heterogeneity. A number of NADH- and NADPH-oxidizing enzymes are concentrated in the upper part of the gradient and exhibit a certain degree of separation from G6Pase. Mg⁺⁺-ATPase and AMPase are enriched in the lower part of the gradient. No specific enrichment of newly synthesized NADPH-cytochrome c reductase activity occurs in any of the subfractions after phenobarbital treatment. These data demonstrate that smooth microsomes, by adequate fractionation procedure, can be separated into subfractious of heterogeneous composition.     

Vesicular Transport of Extracellular Acid Phosphatases in Yeast Saccharomyces cerevisiae

A method for isolation of secretory vesicles from the yeast Saccharomyces cerevisiae based on the disintegration of protoplasts by osmotic shock followed by separation of the vesicles by centrifugation in a density gradient of Urografin was developed in this study. Two populations of the secretory vesicles that differ in density and shape were separated. Acid phosphatases (EC 3.1.3.2) were used as markers of the secretory vesicles. It was shown that the constitutive acid phosphatase (PHO3 gene product) is mainly transported to the cell surface by a lower density population of vesicles, while the repressible acid phosphatase (a heteromer encoded by PHO5, PHO10, and PHO11 genes) by a vesicle population of higher density. These data provide evidence that at least two pathways of transport of yeast secretory proteins from the place of their synthesis and maturation to the cell surface may exist. To reveal the probable reasons for transport of Pho3p and Pho5p/Pho10p/Pho11p enzymes by two different kinds of vesicles, we isolated vesicles from strains that synthesize the homomeric forms of the repressible acid phosphatase. It was demonstrated that glycoproteins encoded by the PHO10 and/or PHO11 genes could be responsible for the choice of one of the alternative transport pathways of the repressible acid phosphatase. A high correlation coefficient between bud formation and secretion of Pho5p phosphatase and the absence of correlation between bud formation and secretion of minor phosphatases Pho10p and Pho11p suggests different functional roles of the polypeptides that constitute the native repressible acid phosphatase.     

Subcellular distribution of the mannan-binding protein and its endogenous inhibitors in rat liver

The subcellular distribution of the mannan-binding protein from rat liver, a lectin specific for mannose and N-acetylglucosamine, was studied. Approximately 75% of the binding activity of the homogenate was recovered in microsomes, approximately 76% of which was accounted for by rough microsomes. Rough microsomes had the highest specific activity of binding, followed by the Golgi apparatus and smooth microsomes, whereas plasma membranes, lysosomes, mitochondria, and the soluble fraction had little or no binding activity. A topographical survey indicated that the binding protein was localized exclusively on the cisternal surface of microsomal vesicles. Thus, the binding protein of microsomal vesicles was protected from protease digestion and was released from the vesicles by mild detergent treatment. Competitive inhibitors, which presumably represent endogenous ligands of the binding protein, were found among subcellular fractions. More than 50% of the inhibitory activity of the homogenate was recovered in rough microsomes, while the highest specific activity of inhibition was found in lysosomes. The K_i values estimated for rough microsomes and lysosomes were 25.9 and 8.67 μg/ml, respectively. The distribution profiles of inhibitors were correlated roughly with those of the binding protein, resulting in masking of the binding activity in organelles up to the level of 86%. On the basis of the known localization and topology of the binding protein and endogenous inhibitors (ligands), possible physiological functions of the binding protein relevant to the transport of biosynthetic intermediates of glycoproteins from the rough endoplasmic reticulum to the Golgi apparatus and from the Golgi apparatus to lysosomes were discussed.     

Inhibition by amiloride of sodium transport into rabbit kidney medulla microsomes

Sodium transport into rabbit kidney medulla microsomes was 50% inhibited by amiloride. This Na⁺ uptake was shown to represent transport when the uptake process was reversed by the ionophore nigericin. The transport was complete within 60 min and proportional to the microsomal protein concentration. The effect of amiloride on transport was specific since the similar compound sulfaguanidine failed to affect microsomal Na⁺ transport. Amiloride-sensitive Na⁺ transport into microsomes was inhibited 70% by decreasing the pH (from 7.0 to 5.9), but was unaffected by the presence of a pH gradient. The kinetics of Na⁺ transport could be explained by a simple model, assuming that amiloride lowered the rate of Na⁺ entrance into the vesicles but had no effect on the rate of efflux. The failure of amiloride to effect efflux from the vesicles was also demonstrated directly.     

Coalescence of microsomal vesicles from rat liver: a phenomenon occurring in parallel with enhancement of the glycosylation activity during incubation of stripped rough microsomes with GTP

Rough microsomes from rat liver have been subjected to various treatments and incubated afterwards with UDP-N-acetyl-[14C]glucosamine and GDP-mannose in the presence of GTP (0.5 mM), or of other nucleotides. In agreement with earlier results from this laboratory, the preparations previously treated to strip off the ribosomes and incubated in the presence of GTP assembled dolichol-linked oligosaccharides and transferred these oligosaccharides to endogenous protein acceptors much more actively than untreated preparations, or stripped preparations incubated in the absence of GTP. Thin-section and freeze-fracture electron microscopy have revealed that pyrophosphate- treated preparations incubated with GTP are aggregated and contain numerous vesicles as large as 1-4 micrometer, or more. Such large vesicles were not present before incubation and thus were considered to have been formed through coalescence of regular-sized ones. Like glycosylation, the coalescence phenomenon depends upon the removal of ribosomes, because it occurred whether ribosomes had been stripped, at least partly, with pyrophosphate, KCl, or puromycin, but not when rough microsomes had been washed with 0.25 M sucrose or with KCl and MgCl2. Like glycosylation, it also depends on the addition of GTP and was not induced by ATP, UTP, CTP, and nonhydrolysable analogues of GTP. Rough microsomes coalesced, however, when pyrophosphate-treated preparations were incubated with GTP in the absence of nucleotide sugars, or in the presence f tunicamycin, indicating that the coalescence phenomenon does not result from the glycosylation of some membrane constituents.     

Subcellular fractionation of rainbow trout gonads with emphasis on microsomal enzymes involved in steroid metabolism

Summary Rainbow trout gonads were subfractionated by differential centrifugation with emphasis on obtaining preparations suitable for the study of steroid-metabolizing enzymes. A fractionation scheme was evaluated for the mature testis and for 3 ovarian developmental stages. The distribution of cell organelles among the fractions was determined using enzyme-markers and electron microscopy. The fractionation scheme was found to be suitable for separating mitochondria and microsomes which were recovered at similar yields to those that had been reported for other extraheptic fish tissues. Fractionation of the mature ovary was fraught with problems probably because a large yolk protein cytosole fraction interfered with the recovery of microsomes. However, no difference in the specific activity of microsomal NADPH-cytochrome c-reductase between the various organ preparations was evident. The testis microsomes contained detectable amounts of cytochrome P450, whereas its content in the various ovary microsomes was too low to be detected. Progesterone 17-hydroxylase was detected in microsomes from testes and early developing ovaries, and microsomal aromatase activity was present in microsomes from early developing, mature and postovulatory ovaries. Furthermore, the testis microsomes contained a highly active UDP glucuronosyltransferase with testosterone used as a substrate.     

Preparation and characterization of total,rough and smooth microsomes from the lung of control and methylcholanthrene-treated rats

Optimal conditions for the preparation of relatively pure microsomes and microsomal subfractions from rat lung have been determined. The most important of these conditions is homogenization of a 20% (w/v) suspension of lung tissue in 0.44 M sucrose/1% (w/v) bovine serum albumin with four up-and-down strokes at 440 rev./min in a Potter-Elvehjem homogenizer. The 10 000 × g supernatant prepared from this homogenate can be centrifuged at 105 000 × g to obtain total microsomes or subfractionated into rough and smooth microsomes on a Cs⁺-containing discontinuous sucrose gradient. The total, rough and smooth microsomes have been characterized in terms of their chemical composition, enzymatic activity, and morphology. These preparations should prove useful in studies of various enzymes in lung (e.g. benzpyrene monooxygenase, epoxide hydrase, enzymes of phospholipid and ascorbic acid synthesis) and in subfractionations designed to reveal heterogeneites in the lateral plane of the lung endoplasmic reticulum.     

INTRACELLULAR TRANSPORT OF SECRETORY PROTEINS IN THE PANCREATIC EXOCRINE CELL : I. Role of the Peripheral Elements of the Golgi Complex

It has been established by electron microscopic radioautography of guinea pig pancreatic exocrine cells (Caro and Palade, 1964) that secretory proteins are transported from the elements of the rough-surfaced endoplasmic reticulum (ER) to condensing vacuoles of the Golgi complex possibly via small vesicles located in the periphery of the complex. To define more clearly the role of these vesicles in the intracellular transport of secretory proteins, we have investigated the secretory cycle of the guinea pig pancreas by cell fractionation procedures applied to pancreatic slices incubated in vitro. Such slices remain viable for 3 hr and incur minimal structural damage in this time. Their secretory proteins can be labeled with radioactive amino acids in short, well defined pulses which, followed by cell fractionation, makes possible a kinetic analysis of transport. To determine the kinetics of transport, we pulse-labeled sets of slices for 3 min with leucine-¹⁴C and incubated them for further +7, +17, and +57 min in chase medium. At each time, smooth microsomes ( = peripheral elements of the Golgi complex) and rough microsomes ( = elements of the rough ER) were isolated from the slices by density gradient centrifugation of the total microsomal fraction. Labeled proteins appeared initially (end of pulse) in the rough microsomes and were subsequently transferred during incubation in chase medium to the smooth microsomes, reaching a maximal concentration in this fraction after +7 min chase incubation. Later, labeled proteins left the smooth microsomes to appear in the zymogen granule fraction. These data provide direct evidence that secretory proteins are transported from the cisternae of the rough ER to condensing vacuoles via the small vesicles of the Golgi complex.