Intracellular and transcellular transport of secretory component and albumin in rat hepatocytes

The intra- and transcellular transports of hepatic secretory and membrane proteins were studied in rats in vivo using [3H]fucose and [35S]cysteine as metabolic precursors. Incorporated radioactivity in plasma, bile, and liver subcellular fractions was measured and the labeled proteins of the Golgi complex, bile, and plasma were separated by SDS PAGE and identified by fluorography. 3H-radioactivity in Golgi fractions peaked at 10 min postinjection (p.i.) and then declined concomitantly with the appearance of labeled glycoproteins in plasma. Maximal secretion of secretory fucoproteins from Golgi occurred between 10 and 20 min p.i. In contrast, the clearance of labeled proteins from Golgi membrane subfractions occurred past 30 min p.i., indicating that membrane proteins leave the Golgi complex at least 30 min later than the bulk of content proteins. A major 80,000-dalton form of secretory component (SC) was identified in the bile by co-precipitation with (IgA)2 by an anti-IgA antibody. An antibody (raised in rabbit) against the biliary 80,000-dalton peptide recognized two larger forms (116,000 and 94,000 dalton), presumably precursors, in Golgi membranes. A comparative study of kinetics of transport of 35S-SC and 35S-albumin showed that albumin peaked in bile at approximately 45 min p.i., whereas the SC peak occurred at 80 min p.i., suggesting that the transit time differs for plasma and membrane proteins that are delivered to the bile canaliculus.     

Identification of thyroid hormone receptors in rat liver nuclei by photoaffinity labeling with L-thyroxine and triiodo-L-thyronine

Photoaffinity labeling of rat liver nuclear extract with underivatized thyroid hormones was performed after incubation with 1 nM [3',5'-125I]thyroxine ([125I]T4) or [3'-125I]triiodothyronine [( 125I]T3) by irradiation with light above 300 nm. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the covalently photolabeled nuclear extract revealed four distinct hormone binding proteins of molecular masses 96, 56, 45, and 35 kilodaltons (kDa), respectively. Distribution of the hormone among these proteins was similar for T4 and T3. The 56- and 45-kDa proteins were the most prominently labeled. The specificity of the photoattachment of thyroid hormones to these nuclear proteins was verified by the irradiation of eight randomly chosen proteins and two proteins known to have thyroid hormone binding sites, human thyroxine binding globulin and bovine serum albumin. Only the latter two were photolabeled with [125I]T4. Competition studies performed by incubating nuclear extracts with [125I]T4 or [125I]T3 in the presence of increasing amounts of the corresponding unlabeled hormone (10-, 100-, and 1000-fold molar excess) demonstrated that (1) photoattachment of labeled T3 or T4 to the 56- and 45-kDa proteins was inhibited by 67-78% and 73-85%, respectively, after incubation with a 1000-fold molar excess of unlabeled hormone, (2) in the presence of lower molar excesses of the corresponding competitor (10- and 100-fold), photoattachment of labeled T3 or T4 to the 56- and 45-kDa receptors was gradually inhibited to a similar extent on both proteins, and (3) the 35- and 96-kDa proteins, although having thyroid hormone binding sites, display lower binding activities since the inhibition of photoattachment of labeled T3 or T4 by a 1000-fold molar excess of unlabeled hormone did not exceed 30-42% and 26-49%, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Fatty acid-acylated proteins in secretory mutants of Saccharomyces cerevisiae.

Yeast secretory (sec) mutants that are blocked in the transport of secretory proteins and accumulate membrane organelles were used to study the biosynthesis of fatty acid-acylated proteins. Four proteins were labeled with [3H]palmitate in sec mutants accumulating endoplasmic reticulum membranes. Three of these (molecular weights approximately equal to 20,000, 50,000, and 120,000) were N-linked glycoproteins, based on their ability to be labeled with [3H]mannose and their sensitivity to endoglycosidase H. The fourth protein (molecular weight approximately equal to 30,000) also was labeled with [3H]mannose but was insensitive to endoglycosidase H; it appeared to contain O-linked sugars. In sec mutants accumulating Golgi membranes or post-Golgi vesicles, a 35-kilodalton protein was labeled with [3H]palmitate. Analysis of Staphylococcus aureus protease V8 digests and pulse-chase experiments indicated that the 30-kilodalton protein was a precursor of 35 kilodaltons. None of these proteins was labeled with [3H]palmitate in a sec mutant that blocked the penetration of nascent polypeptides into endoplasmic reticulum; thus, acylation occurred in endoplasmic reticulum. All four proteins could be recovered from fractions enriched for yeast membranes. Fatty acids were not released from proteins by boiling in sodium dodecyl sulfate or extraction with organic solvents but were recovered as methyl esters after proteins were treated with KOH-methanol, a reaction characteristic of an acyl ester linkage.     

Kinetics of intracellular transport and sorting of lysosomal membrane and plasma membrane proteins

We have used monospecific antisera to two lysosomal membrane glycoproteins, lgp120 and a similar protein, lgp110, to compare the biosynthesis and intracellular transport of lysosomal membrane components, plasma membrane proteins, and lysosomal enzymes. In J774 cells and NRK cells, newly synthesized lysosomal membrane and plasma membrane proteins (the IgG1/IgG2b Fc receptor or influenza virus hemagglutinin) were transported through the Golgi apparatus (defined by acquisition of resistance to endo-beta-N-acetylglucosaminidase H) with the same kinetics (t1/2 = 11-14 min). In addition, immunoelectron microscopy of normal rat kidney cells showed that lgp120 and vesicular stomatitis virus G-protein were present in the same Golgi cisternae demonstrating that lysosomal and plasma membrane proteins were not sorted either before or during transport through the Golgi apparatus. To define the site at which sorting occurred, we compared the kinetics of transport of lysosomal and plasma membrane proteins and a lysosomal enzyme to their respective destinations. Newly synthesized proteins were detected in dense lysosomes (lgp's and beta-glucuronidase) or on the cell surface (Fc receptor or hemagglutinin) after the same lag period (20-25 min), and accumulated at their final destinations with similar kinetics (t1/2 = 30-45 min), suggesting that these two lgp's are not transported to the plasma membrane before reaching lysosomes. This was further supported by measurements of the transport of membrane-bound endocytic markers from the cell surface to lysosomes, which exhibited additional lag periods of 5-15 min and half-times of 1.5-2 h. The time required for transport of newly synthesized plasma membrane proteins to the cell surface, and for the transport of plasma membrane markers from the cell surface to lysosomes would appear too long to account for the rapid transport of lgp's from the Golgi apparatus to lysosomes. Thus, the observed kinetics suggest that lysosomal membrane proteins are sorted from plasma membrane proteins at a post-Golgi intracellular site, possibly the trans Golgi network, before their delivery to lysosomes.     

Nucleocytoplasmic traffic of proteins.

We have used the synchronized formation of a mixed cytoplasm upon heterokaryon formation as a model for investigating the cisternal-specific transport of resident proteins between neighboring Golgi apparatus. Rat NRK and hamster 15B cells were fused by UV-inactivated Sindbis virus and then incubated for various time periods in the presence of cycloheximide. The resident Golgi apparatus proteins, rat GIMPc and Golgp 125, were localized with species-specific monoclonal antibodies. Immunofluorescent colocalization of rat and hamster Golgi membrane proteins was observed with a t1/2 of 1.75 h at 37 degrees C. Colocalization of resident, but not transient, Golgi membrane protein was concomitant with formation of a large extended Golgi complex and was accompanied by the acquisition of endoglycosidase H resistance by preexisting Golgp 125. Dispersal of the extended Golgi complex by nocodazole revealed that colocalization of resident Golgi proteins was due to intermixing of proteins in the same Golgi element rather than overlapping of closely apposed Golgi structures. Incubation of the polykaryons at 20 degrees C inhibited both the colocalization of GIMPc and Golgp 125 and the formation of an extended Golgi complex. Little change in the number of cisternae/stack in cross sections of the Golgi apparatus was observed upon cell fusion, and in the extended Golgi complex the hamster resident protein remained localized to one side of the Golgi stack. Surprisingly, the morphological identity of the rat and hamster Golgi units appeared to be maintained in the heterokaryons. These results suggest that the intermixing of resident Golgi membrane proteins requires direct physical continuity between Golgi elements and that resident Golgi membrane proteins are preferentially excluded from the non-clathrin-coated transport vesicles budding from Golgi cisternae.     

ADP ribosylation factor and a 14-kD polypeptide are associated with heparan sulfate-carrying post-trans-Golgi network secretory vesicles in rat hepatocytes

Constitutive secretory vesicles carrying heparan sulfate proteoglycan (HSPG) were identified in isolated rat hepatocytes by pulse-chase experiments with [35S]sulfate and purified by velocity-controlled sucrose gradient centrifugation followed by equilibrium density centrifugation in Nycodenz. Using this procedure, the vesicles were separated from plasma membranes, Golgi, trans-Golgi network (TGN), ER, endosomes, lysosomes, transcytotic vesicles, and mitochondria. The diameter of these vesicles was approximately 100-200 nm as determined by electron microscopy. A typical coat structure as described for intra- Golgi transport vesicles or clathrin-coated vesicles could not be seen, and the vesicles were not associated with the coat protein beta-COP. Furthermore, the vesicles appear to represent a low density compartment (1.05-1.06 g/ml). Other constitutively secreted proteins (rat serum albumin, apolipoprotein E, and fibrinogen) could not be detected in purified HSPG-carrying vesicles, but banded in the denser fractions of the Nycodenz gradient. Moreover, during pulse-chase labeling with [35S]methionine, labeled albumin did not appear in the post-TGN vesicle fraction carrying HSPGs. These findings indicate sorting of HSPGs and albumin into different types of constitutive secretory vesicles in hepatocytes. Two proteins were found to be tightly associated with the membranes of the HSPG carrying vesicles: a member of the ADP ribosylation factor family of small guanine nucleotide-binding proteins and an unknown 14-kD peripheral membrane protein (VAPP14). Concerning the secretory pathway, we conclude from these results that ADP ribosylation factor proteins are not only involved in vesicular transport from the ER via the Golgi to the TGN, but also in vesicular transport from the TGN to the plasma membrane.     

Following the Fate In Vivo of COPI Vesicles Generated In Vitro

COPI vesicles are a class of transport carriers that function in the early secretory pathway. Their fate and function are still controversial. This includes their contribution to bidirectional transport within the Golgi apparatus and their role during cell division. Here we describe a method that should address several open questions about the fate and function of COPI vesicles in vivo . To this end, fluorescently labeled COPI vesicles were generated in vitro from isolated rat liver Golgi membranes, labeled with the fluorescent dyes Alexa-488 or Alexa-568. These vesicles appeared to be active and colocalized with endogenous Golgi membranes within 30 min after microinjection into mammalian cells. The COPI vesicle-derived labeled membrane proteins could be classified into two types that behaved like endogenous proteins after Brefeldin A treatment.     

Identification of human sperm surface glycoproteins recognized by autoantisera from immune infertile men, women, and vasectomized men

To identify the surface antigens of human sperm recognized by antisera from immune infertility patients and vasectomized men, we labeled sperm surface proteins with 125I- and used patient antisera for immunoprecipitation. Sera were studied from 27 infertile males, 18 infertile females, and 4 vasectomized males, each possessing anti-sperm antibodies detected by immunobead binding. Sera from different infertile males, different infertile females, and vasectomized males were remarkably similar in their surface antigen recognition. The different sera specifically immunoprecipitated the same small group of 125I-labeled surface proteins, which included polypeptides in the region 90 kDa, 40-45 kDa, and 26 kDa. Treatment with N-glycanase showed that the proteins of 90 kDa, 40-45 kDa, and 26 kDa were glycoproteins with N-linked carbohydrate. The immunoprecipitated 125I-labeled proteins and the total extract of 125I-labeled surface proteins were compared on two-dimensional (2D) gels. The results show the 90 kDa polypeptide is a major sperm surface component, whereas 40-45 kDa and 26 kDa polypeptides are minor components. The 2D gel comparison also indicates that 90 kDa, 40-45 kDa, and 26 kDa are a small subset of the total ensemble of sperm surface proteins. Clinical data suggest antibodies to these few proteins interfere with sperm function.     

Passage of serum-destined proteins through the Golgi apparatus of rat liver. An examination of heavy and light Golgi fractions

The participation of hepatic Golgi apparatus in the intracellular transport of blood-destined proteins has been analyzed using Golgi fractions enriched in cis and trans components of the Golgi apparatus. SDS-polyacrylamide gel electrophoresis of the liver Golgi fractions showed several proteins corresponding in relative proportions and mobilities with serum proteins. After a pulse injection of labeled leucine, the secretory content of the cis Golgi fraction was labeled earlier than the trans Golgi fraction. Taken together, the results show the participation of the liver Golgi apparatus in the secretion of most of the serum proteins and provide documentation for a sequential progression of secretory protein through the cis and trans components of the Golgi apparatus.     

Transcellular transport of polymeric IgA in the rat hepatocyte: biochemical and morphological characterization of the transport pathway

Polymeric IgA (pIgA) is transported by liver parenchymal cells (hepatocytes) from blood to bile via a receptor-mediated process. We have studied the intracellular pathway taken by a TEPC15 mouse myeloma pIgA. When from 1 microgram to 1 mg 125I-pIgA was injected into the saphenous vein of a rat, 36% was transported as intact protein into the bile over a 3-h period. The concentration of transported 125I-pIgA was maximal in bile 30-60 min after injection, and approximately 80% of the total 125I-pIgA ultimately transported had been secreted into bile by 90 min. A horseradish peroxidase-pIgA conjugate (125I-pIgA-HRP) was transported to a similar extent and with kinetics similar to that of unconjugated 125I-pIgA and was therefore used to visualize the transport pathway. Peroxidase cytochemistry of livers fixed in situ 2.5 to 10 min after 125I-pIgA-HRP injection demonstrated a progressive redistribution of labeled structures from the sinusoidal area to intermediate and bile canalicular regions of the hepatocyte cytoplasm. Although conjugate-containing structures began accumulating in the bile canalicular region at these early times, no conjugate was present in bile until 20 min. From 7.5 to 45 min after injection approximately 30% of the labeled structures were in regions that contained Golgi complexes and lysosomes; however, we found no evidence that either organelle contained 125I-pIgA-HRP. At least 85% of all positive structures in the hepatocyte were vesicles of 110-160-nm median diameters, with the remaining structures accounted for by tubules and multivesicular bodies. Vesicles in the bile canalicular region tended to be larger than those in the sinusoidal region. Serial sectioning showed that the 125I-pIgA-HRP-containing structures were relatively simple (predominantly vesicular) and that extensive interconnections did not exist between structures in the sinusoidal and bile canalicular regions.     

Changes in the random distribution of sialic acid at the surface of the myeloid sinusoidal endothelium resulting from the presence of diaphragmed fenestrae

Frog exocrine pancreatic tissue was studied in vitro under conditions which maintain the differences between tissues from fasted and fed animals. Sodium dodecyl sulfate (SDS) gel electrophoresis after labeling with [14C]amino acids showed that feeding stimulated the synthesis of secretory proteins to the same relative degree as the overall protein synthesis. The intracellular transport of secretory proteins was studied by electronmicroscopy autoradiography after pulse-labeling with [3H]leucine. It was found that the transport route is similar under both feeding conditions. After their synthesis in the rough endoplasmic reticulum (RER), the proteins move through the peripheral elements and cisternae of the Golgi system into the condensing vacuoles. The velocity of the transport increases considerably after feeding. When frogs are fasted, the release of labeled proteins from the RER takes greater than 90 min, whereas after feeding, this happens within 30 min. Comparable differences were observed for transport through the Golgi system. The apparent differences between the frog and mammalian pancreas in the regulation of synthesis, intracellular transport, and secretion of proteins are discussed.     

Sorting by COP I-coated vesicles under interphase and mitotic conditions

COP I-coated vesicles were analyzed for their content of resident Golgi enzymes (N-acetylgalactosaminyltransferase; N- acetylglucosaminyltransferase I; mannosidase II; galactosyltransferase), cargo (rat serum albumin; polyimmunoglobulin receptor), and recycling proteins (-KDEL receptor; ERGIC-53/p58) using biochemical and morphological techniques. The levels of these proteins were similar when the vesicles were prepared under interphase or mitotic conditions showing that sorting was unaffected. The average density relative to starting membranes for resident enzymes (14-30%), cargo (16-23%), and recycling proteins (81-125%) provides clues to the function of COP I vesicles in transport through the Golgi apparatus.     

Reinternalization of secretory proteins during membrane recycling in rat pancreatic acinar cells

Membrane recycling in pancreatic acinar cells involves endocytic vesicle formation at the apical cell surface and rapid membrane traffic to the Golgi complex. During this process a small amount of extracellular content is taken up from the acinar lumen. In order to determine whether secretory proteins already released into the pancreatic acinar lumen are reinternalized during membrane retrieval, 3H-labeled amylase or 125I-labeled secretory proteins were reinfused through the pancreatic duct until the lumina were reached. Tissue samples from various time points were prepared for light and electron microscope autoradiography. The observations showed that [3H]amylase and, to a lesser extent, the 125I-labeled secretory proteins were internalized at the apical cell surface and rapidly (within 2-5 min) transferred to the Golgi cisternae and the condensing vacuoles; only a minor proportion of silver grains was observed over lysosomes. In addition, at later time points, mature secretion granules close to the Golgi complex became labeled. The results indicate that exocytosis in the rat exocrine pancreas does not operate at 100% efficiency; part of the exported amylase and part of the total secretion product are reinternalized concomitantly with the endocytic removal of plasma membrane and are copackaged together with newly synthesized secretory proteins.     

Serotonin Binding Protein: Synthesis, Secretion, and Recycling

Abstract: Serotonin binding protein (SBP) is present in all neurectodermally derived cells that store serotonin (5-HT). Three forms of SBP have been detected (68, 56, and 45 kDa), and antibodies to SBP that interfere with the binding of 5-HT react with each of these proteins. The current experiments test two hypotheses: (a) that the 56- and 45-kDa forms of SBP are produced by posttranslational cleavage of a 68-kDa precursor molecule; and (b) that 45-kDa SBP is a constituent of serotonergic secretory vesicles. Pulse-chase experiments were carried out using medullary thyroid carcinoma cells as a model. These neurectodermally derived cells produce 5-HT and all three forms of SBP. Following pulse labeling for 20 min with l -[³⁵S]methionine, the cells were incubated in the presence of an excess of unlabeled l -methionine for 0, 30, 60, or 90 min at 37°C. Alternatively, the chase was performed under conditions (20°C, inhibition of ATP generation) that delay or stop transport of newly synthesized proteins from the rough endoplasmic reticulum through the Golgi apparatus. Following incubation, the cells were washed and solubilized, and SBP was immunoprecipitated. Radioactive proteins in the immunoprecipitate were electrophoretically resolved and quantified. Immediately after the pulse, each of the three forms of SBP was found to be labeled with ³⁵S. The relative proportions of ³⁵S-labeled 68-, 56-, and 45-kDa SBP remained the same at each interval of chase. These proportions were not changed when the chase was carried out at 20°C or under conditions that blocked the biosynthesis of ATP. These observations suggest that each form of SBP is a primary product of translation, that the smaller forms of SBP are not produced by cleavage from a larger molecule, and that the size of the primary products of translation is not altered by passage to the Golgi apparatus or a post-Golgi compartment. When secretion was induced, 45-kDa SBP, but not 56- or 68-kDa SBP, was released to the medium. When antibodies to 45-kDa SBP were added to the medium at the time secretion was induced, antibody binding sites appeared as patches on the cell surfaces. Because of these sites, cells were lysed when they were stimulated to secrete in the presence of antibodies to 45-kDa SBP and guinea pig complement. Antibody binding sites disappeared from cell surfaces after 20 min, at which time antibodies to SBP were found inside the cells. It is suggested that 45-kDa SBP is packaged with 5-HT in secretory vesicles. Some 45-kDa SBP is lost during secretion as a result of exocytosis; however, a fraction of the 45-kDa SBP remains bound to the luminal surface of the membrane of secretory vesicles. This protein is exposed to the ambient medium as a consequence of exocytosis, but is reinternalized when the vesicular membrane is recaptured during vesicle recycling.     

The effects of low temperatures on intracellular transport of newly synthesized albumin and haptoglobin in rat hepatocytes.

Isolated rat hepatocytes were pulse-labelled with [35S]methionine at 37 degrees C and subsequently incubated (chased) for different periods of time at different temperatures (37-16 degrees C). The time courses for the secretion of [35S]methionine-labelled albumin and haptoglobin were determined by quantitative immunoprecipitation of the detergent-solubilized cells and of the chase media. Both proteins appeared in the chase medium only after a lag period, the length of which increased markedly with decreasing chase temperature: from about 10 and 20 min at 37 degrees C to about 60 and 120 min at 20 degrees C for albumin and haptoglobin respectively. The rates at which the proteins were externalized after the lag period were also strongly affected by temperature, the half-time for secretion being 20 min at 37 degrees C and 200 min at 20 degrees C for albumin; at 16 degrees C no secretion could be detected after incubation for 270 min. Analysis by subcellular fractionation showed that part of the lag occurred in the endoplasmic reticulum and that the rate of transfer to the Golgi complex was very temperature-dependent. The maximum amount of the two pulse-labelled proteins in Golgi fractions prepared from cells after different times of chase decreased with decreasing incubation temperatures, indicating that the transport from the Golgi complex to the cell surface was less affected by low temperatures than was the transport from the endoplasmic reticulum to the Golgi complex.     

Intracellular vesicles involved in the transport of Semliki Forest virus membrane proteins to the cell surface.

The route of transport of Semliki Forest virus (SFV) membrane glycoproteins to the plasma membrane was studied using immunoperoxidase electron microscopy. SFV glycoproteins were localized in cultured BHK-21 fibroblasts infected with a temperature-sensitive mutant ts-1 of SFV, which shows a temperature-dependent, reversible defect in the transport of membrane glycoproteins to the cell surface. At 39 degrees C (restrictive temperature) the viral proteins were retained in the endoplasmic reticulum and the nuclear membrane. After shift of the infected cultures to 28 degrees C (permissive temperature) the proteins were synchronously transported to the Golgi complex. In the Golgi complex the labeled proteins were first (at 2.5 min) detected in large Golgi-associated vacuoles (GAV). Subsequently, i.e., at 5-30 min, the viral glycoproteins appeared in the cisternal stack: at 5 min the label was found in one or two of the proximal cisternae whereas at 15 or 30 min also the more distal cisternae were partially or uniformly labeled. At all time points examined after the temperature-shift, peroxidase label was found in 50 nm vesicles which were frequently coated. At 30 min, in addition to the 50 nm vesicles, larger 80 nm vesicles, which often had a cytoplasmic coat were labeled in the Golgi region. These results identify two major size classes of both coated and smooth vesicles which appear to function in the transport of the viral membrane proteins from the endoplasmic reticulum via distinct GAV and the stacked Golgi cisternae to the plasma membrane.     

Activation of 5-[125I]iodonaphthyl-1-azide via excitation of fluorescent (N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)) lipid analogs in living cells. A potential tool for identification of compartment-specific proteins and proteins involved in intracellular transport and metabolism of lipids

We describe a new technique for analysis of proteins located near fluorescent lipid analogs in intact living cells using the membrane-permeant, photoactivatable probe, 5-[125I]iodonaphthyl-1-azide ([125I]INA). [125I] INA can be activated directly with UV light or indirectly through excitation of adjacent fluorophores (photosensitizers) with visible light to modify nearby proteins covalently with 125I. In this report we demonstrate that fluorescent phospholipids and sphingolipids containing N-(7-nitrobenz-2-oxa-1,3-diazol-4-yl)-6-aminocaproic acid serve as appropriate photosensitizers for [125I]INA. Using Chinese hamster ovary fibroblasts, we optimized the labeling conditions with respect to lipid concentration and time of irradiation and then examined the profiles of cellular proteins that were labeled when fluorescent analogs of ceramide, sphingomyelin, and phosphatidic acid were used as photosensitizers in living cells. The use of different fluorescent lipids, which label different subcellular compartments of cells as determined by fluorescence microscopy, derivatized different sets of cellular proteins with 125I. The labeled proteins were subsets of the total set of proteins available for derivatization as determined by direct activation of [125I]INA. Most proteins labeled by this procedure were pelleted by centrifugation of cell lysates at high speed (260,000 x g), but several soluble proteins were also labeled under these conditions. The implications of using this technique for identification of compartment-specific proteins and proteins involved in lipid metabolism and transport are discussed.     

Two forms of plasma membrane-intercalated heparan sulfate proteoglycan in rat ovarian granulosa cells. Labeling of proteoglycans with a photoactivatable hydrophobic probe and effect of the membrane anchor-specific phospholipase C

The structures of cell-associated heparan sulfate (HS) proteoglycans and their interaction with the plasma membrane was studied using rat ovarian granulosa cell culture. HS proteoglycans were either metabolically labeled by incubating cell cultures with [3H] leucine and [35S]sulfate or labeled in plasma membrane preparations with a photoactivatable reagent, 3-(trifluoromethyl)-3-(m-[125I]iodophenyl)diazirine (TID), a compound which has been shown to selectively label the hydrophobic membrane-binding domains of several proteins. After purification of HS proteoglycans from the labeled cell cultures or from the labeled membrane preparations by repeated Q-Sepharose ion exchange chromatography in 8 M urea, they were analyzed by Superose 6 gel filtration and octyl-Sepharose chromatography both in 4 M guanidine HCl. The results indicated that the HS proteoglycans were labeled with 125I and therefore have an intramembranous domain. Phospholipase C (Bacillus thuringiensis), which specifically cleaves phosphatidylinositol membrane anchors, released approximately 25% of the 35S-labeled HS proteoglycans from the cell surface as well as 20-30% of the 125I-label from the 125I-TID-labeled HS proteoglycans. These data indicate that a subpopulation of HS proteoglycans are intercalated into the plasma membrane through a linkage structure involving phosphatidylinositol. Phospholipase C-resistant, 125I-labeled HS proteoglycans represent those species inserted into membrane through an intercalated peptide sequence. Core protein size of phosphatidylinositol-anchored species estimated by polyacrylamide gel electrophoresis after heparitinase digestion was approximately 80 kDa, and it was significantly larger than that of the directly intercalated species (approximately 70 kDa).     

The (Na+ + K+)-ATPase of chick sensory neurons. Studies on biosynthesis and intracellular transport

The (Na+ + K+)-ATPase of cultured chick sensory neurons was studied with the aid of antibodies specific for this enzyme. Immunofluorescent labeling indicated the (Na+ + K+)-ATPase is evenly distributed on the neuronal cell surface; cell bodies, neurites, and growth cones were labeled with comparable intensity. Pulse-chase experiments with [35S]methionine, followed by immunoprecipitation, indicated concurrent synthesis and rapid association of the alpha (Mr = 105,000) and beta (Mr = 47,000) subunits. The alpha subunit is oligosaccharide-free while the beta subunit contains three Asn-linked oligosaccharide chains attached to a core peptide of 32,000 molecular weight. The time required for oligosaccharide processing of the newly synthesized beta subunit to endoglycosidase H-resistance suggests the (Na+ + K+)-ATPase takes 45-60 min to move from the site of polypeptide synthesis to the Golgi apparatus. Significantly less time was required for transport through the Golgi apparatus and insertion in the plasma membrane. From 30% to 55% of the newly synthesized (Na+ + K+)-ATPase did not appear on the cell surface but accumulated intracellularly. When tunicamycin was used to inhibit glycosylation of the beta subunit, there was no effect upon subunit assembly, intracellular transport, or degradation rate (t1/2 = 40 h).     

Differential arrest of secretory protein transport in cultured rat hepatocytes by azide treatment

The effect of reduced cellular ATP content on intracellular transport of two secretory proteins, albumin and haptoglobin, in isolated rat hepatocytes was studied. The cells were labeled with [35S]methionine and the cellular ATP content was then rapidly reduced to different stable levels by incubation with azide at different concentrations (2.0- 10 mM). The amount of the radioactively labeled secretory proteins in the cells and in the medium after 150 min of incubation was determined by immunoprecipitation followed by gel electrophoresis, fluorography, and densitometry. At progressively lower ATP levels, down to 50% of normal, the protein secretion was unaffected, whereas at even lower levels an increasing portion of the proteins remained in the cells; at 30 and 10% of normal ATP level, 25 and 75% of albumin, respectively, was arrested intracellularly. Analysis of the carbohydrate structure of intracellularly arrested haptoglobin showed that in cells with an ATP level of approximately 30% of normal, the majority of haptoglobin molecules (55%) were fully or partially resistant to endoglycosidase H. This result indicates that exit from the medial and/or the trans part of the Golgi complex (GC) was inhibited under these conditions. It also shows that the protein had accumulated in the GC, since under normal conditions the fraction of the intracellular haptoglobin that is endoglycosidase H resistant is approximately 10%. By similar criteria it was found that at ATP levels below 10% of normal transport of haptoglobin from the endoplasmic reticulum to the medial GC (and possibly also to the cis GC) as well as from the trans GC to the medium were blocked.