A quantitative model of traffic between plasma membrane and secondary lysosomes: evaluation of inflow, lateral diffusion, and degradation

We present here a mathematical model that accounts for the various proportions of plasma membrane constituents occurring in the lysosomal membrane of rat fibroblasts (Draye, J.-P., J. Quintart, P. J. Courtoy, and P. Baudhuin. 1987. Eur. J. Biochem. 170: 395-403; Draye, J.-P., P. J. Courtoy, J. Quintart, and P. Baudhuin. 1987. Eur. J. Biochem. 170:405-411). It is based on contents of plasma membrane markers in purified lysosomal preparations, evaluations of their half-life in lysosomes and measurements of areas of lysosomal and plasma membranes by morphometry. In rat fibroblasts, structures labeled by a 2-h uptake of horseradish peroxidase followed by a 16-h chase (i.e., lysosomes) occupy 3% of the cellular volume and their total membrane area corresponds to 30% of the pericellular membrane area. Based on the latter values, the model predicts the rate of inflow and outflow of plasma membrane constituents into lysosomal membrane, provided their rate of degradation is known. Of the bulk of polypeptides iodinated at the cell surface, only 4% reach the lysosomes every hour, where the major part (integral of 83%) is degraded with a half-life in lysosomes of integral to 0.8 h. For specific plasma membrane constituents, this model can further account for differences in the association to the lysosomal membrane by variations in the rate either of lysosomal degradation, of inflow along the pathway from the pericellular membrane to the lysosomes, or of lateral diffusion.     

Relations between plasma membrane and lysosomal membrane. 2. Quantitative evaluation of plasma membrane marker enzymes in the lysosomes

We have quantified, in cultured rat fibroblasts, the association to the lysosomal membrane of two classical plasma membrane markers, 5'-nucleotidase and alkaline phosphodiesterase I. To isolate highly purified lysosomal preparations, lysosomes were loaded with horseradish peroxidase (2-h cell uptake, 16-h chase) and isolated by isopycnic centrifugation in linear Percoll gradients, followed by a 3,3'-diaminobenzidine-induced density shift in sucrose gradients. Purified lysosomal preparations contained up to 50% of N-acetyl-beta-glucosaminidase of the homogenate. This lysosomal enzyme was enriched 33-fold in the most purified preparations. In the electron microscope, these preparations appeared to be highly purified and only contained organelles filled with diaminobenzidine reaction products. Analysis of purified preparations indicates that 0.5-0.8% of 5'-nucleotidase, but as much as 10.9-14.3% of alkaline phosphodiesterase I activities of the homogenate, are associated with lysosomes. After freezing-thawing, these activities remained essentially membrane-associated. The larger value obtained for alkaline phosphodiesterase I could not be ascribed to other lysosomal enzymes, as no such activity was detected at acidic pH. These two plasma membrane markers are thus unevenly distributed in the lysosomal compartment.     

Cell surface glycoproteins of CHO cells. I. Internalization and rapid recycling

The major cell surface proteins of Chinese hamster ovary (CHO) cells have been investigated after reacting cells at 4 degrees C with the membrane-impermeant reagent, trinitrobenzenesulfonate (TNBS). Immunoprecipitation and subsequent two-dimensional, sodium-dodecyl sulfate, polyacrylamide gel electrophoresis (SDS-PAGE) of proteins from derivatized cells that had been labelled previously with [3H]D-glucosamine or [3H]L-leucine showed that TNBS reacted with most of the high molecular weight (HMW) acidic glycoproteins that became labelled with iodine by the lactoperoxidase technique and that bind the lectin, wheat germ agglutinin (WGA). After warming the cells to allow endocytosis to proceed, molecules haptenized with trinitrophenol (TNP) groups were followed radiochemically by means of [125I]anti-DNP antibodies. The half-life for internalization of proteins tagged with either [125I]anti-DNP IgG or Fab averaged about 5 min. A similar result was obtained when a monoclonal antibody directed against a single plasma membrane glycoprotein was used, or when the rate of surface loss of TNP groups unoccupied by antibodies was measured. Within 15 min at 37 degrees C, a steady-state between surface and cytoplasmic label was reached, with about 65% of the hapten located internally. Recycling of internalized TNP groups back to the cell surface also occurred rapidly (t 1/2 approximately 5 min). Most of the intracellular radioactivity was associated with a membrane fraction of density similar to that of the plasma membrane. Over a 4-h period, there was no significant entry of labeled molecules into lysosomes. By contrast, the fluid-phase marker, horseradish peroxidase, became associated with the lysosomes within 1 h. Our results are consistent with the view that the majority of plasma membrane glycoproteins are continuously being internalized and recycled at a high rate.     

Turnover of the plasma membrane proteins of hepatoma tissue culture cells.

The turnover of the plasma membrane proteins of hepatoma tissue culture cells was examined by three different methods--loss of polypeptides labeled in situ by lactoperoxidase-catalyzed iodination, loss of membrane polypeptides labeled with amino acid precursors, and loss from the membrane of fucose-labeled polypeptides. In both logarithmically growing and density-inhibited cells the proteins of the membrane are degraded with a half-life of about 100 hours. This is longer than the half-life of total cell protein, 50 to 60 hours, and longer than the doubling time of the cells, about 30 hours. Similar values for the rate of degradation of the membrane proteins were obtained by each of the three techniques. The same fucose-labeled polypeptides are present in the microsomal and the plasma membrane fractions of hepatoma tissue culture cells as analyzed by electrophoresis in dodecyl sulfate-acrylamide gels. But the fucose-labeled polypeptides were lost from the microsomal fraction at a faster rate than from the plasma membrane. Autoradiographic and double labeling techniques using 125I and 131I, or [3H]leucine and [14C]leucine were used to measure the relative rates of degradation of the proteins in the plasma membrane. All of the leucine-labeled polypeptides and the iodinated polypeptides had similar rates of degradation. These results support a model for the biogenesis of the plasma membrane in which the proteins are incorporated and removed in large structural units.     

A fluorescent residualizing label for studies on protein uptake and catabolism in vivo and in vitro.

Residualizing labels are tracers which remain in lysosomes after uptake and catabolism of the carrier protein and have been especially useful for studies on the sites of plasma protein degradation. Thus far these labels have contained radioactive reporters such as 3H or 125I. In the present paper we describe a fluorescent residualizing label, NN-dilactitol-N'-fluoresceinylethylenediamine (DLF). Modification of asialofetuin (ASF) or rat serum albumin (RSA) with DLF affected neither their normal kinetics of clearance from the rat circulation nor their normal tissue sites of uptake and degradation. After injection of DLF-ASF, fluorescent degradation products were recovered nearly quantitatively in liver and retained with a half-life of about 2 days. Fluorescent degradation products from DLF-RSA were recovered in skin and muscle, and were localized in fibroblasts by fluorescence microscopy. These results confirm previous studies with radioactive residualizing labels in which fibroblasts in peripheral tissues were identified as primary sites of albumin degradation. Fluorescent catabolites also accumulated in fibroblasts incubated with DLF-RSA in vitro, and residualized with a half-life of about 2 days. Overall, the data establish that DLF functions efficiently as a fluorescent residualizing label both in vivo and in vitro. The advantages of fluorescent, compared with radioactive, residualizing labels should make them valuable tools for studies on protein uptake and catabolism in biological systems.     

Sorting of an internalized plasma membrane lipid between recycling and degradative pathways in normal and Niemann-Pick, type A fibroblasts

We examined the metabolism and intracellular transport of a fluorescent sphingomyelin analogue, N-(N-[6-[(7-nitrobenz-2-oxa-1,3-diazol-4-yl)amino]caproyl])- sphingosylphosphorylcholine (C6-NBD-SM), in both normal and Niemann-Pick, type A (NP-A) human skin fibroblast monolayers. C6-NBD-SM was integrated into the plasma membrane bilayer by transfer of C6-NBD-SM monomers from liposomes to cells at 7 degrees C. The cells were washed, and within 3 min of warming to 37 degrees C, both normal and NP-A fibroblasts had internalized C6-NBD-SM from the plasma membrane, resulting in a punctate pattern of intracellular fluorescence. Rates for C6-NBD-SM internalization and transport from intracellular compartments to the plasma membrane (recycling) were similar for normal and NP-A cells. With increasing time at 37 degrees C, internalized C6-NBD-SM accumulated in the lysosomes of NP-A fibroblasts, while normal fibroblasts showed increasing Golgi apparatus fluorescence with no observable lysosomal labeling. Since NP-A fibroblasts lack lysosomal (acid) sphingomyelinase (A-SMase), this result suggested that hydrolysis of C6-NBD-SM prevented its accumulation in the lysosomes of normal fibroblasts during its transport along the degradative pathway. We used the amount of C6-NBD-SM hydrolysis by A-SMase in normal cells as a measure of C6-NBD-SM transported from the cell surface to the lysosomes. After a lag period, C6-NBD-SM was delivered to the lysosomes at a rate of approximately 8%/h. This rate was approximately 18-19 fold slower than the rate of C6-NBD-SM recycling from intracellular compartments to the plasma membrane. Thus, small amounts of C6-NBD-SM were transported along the degradative pathway, while most endocytosed C6-NBD-SM was sorted for transport along the plasma membrane recycling pathway.     

Isolation and preliminary characterization of the major membrane boundaries of the endocytic pathway in lymphocytes

Plasma membrane, coated pits, endosomes, and lysosomes were isolated from a mouse T lymphoma cell line using a density shift protocol in which these compartments were selectively loaded with gold conjugates. The plasma membrane was prepared after selective labeling for 1 h at 2 degrees C with gold-ricin and gave a yield of 40% according to enzymatic and antigenic markers. Endosomes were obtained by loading the cells for 2 h at 22 degrees C with gold complexed to an antimouse transferrin receptor mAb. Coated pits were isolated using a similar procedure, but after an incubation at 10 degrees C, which allowed deep invagination of the pits but prevented internalization. The yield (calculated using the recovery of [125I]transferrin) was 32% for endosomes and 10% for coated pits. Finally lysosomes were prepared by loading the cells for 18 h at 37 degrees C with gold low density lipoproteins (LDLs) followed by a 3-h chase at 37 degrees C with LDL alone. The final lysosome yield (based on the recovery of lysosomal enzymes) was 16%. Studies of the protein composition of these cellular compartments on two-dimensional gels showed that while some major proteins are present throughout the pathway, specific proteins can be identified in each of the isolated fractions. The greatest change in the pattern of protein constituents seen along the pathway was between endosomal and lysosomal preparations.     

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.     

Pathways of endocytosis in cultured macrophages. Electron microscopic autoradiographic tracing of iodinated plasma membrane proteins

Lactoperoxidase-mediated iodination at 4 degrees C--an established method for covalent labelling of plasma membrane proteins--and quantitative electron microscopic autoradiography were used to follow the pathways of endocytosis in mouse macrophages in vitro. Directly after the labelling, the autoradiographic grains were concentrated to the cell surface. After warming to 37 degrees C, radioactive material was rapidly internalized into cytoplasmic vesicles and subsequently transferred to lysosomes as well as to the Golgi complex. Maximum grain density (% grains/% volume) over the vesicles was observed after 15 min, over the lysosomes after 30 to 45 min and over the Golgi complex after 30 and 90 min. Throughout the experimental period (120 min), the vesicles showed the largest fraction of intracellular grains, but higher grain densities occurred in lysosomes as well as in stacked Golgi cisternae and Golgi-associated vesicles. In spite of the internalization process, the labelling of the cell surface came to a steady state already after 30 min and at all intervals more than 50% of the autoradiographic grains were localized to this compartment. About 25% of the cell-associated radioactivity was lost rapidly with a half-life of 20 to 25 min and the remaining 75% slowly with a half-life of 7 to 9 h. The results indicate that membrane internalized by endocytosis partly follows a route to the lysosomes and that, additionally, there exists a route to and through the Golgi complex. They further support earlier notions of a bidirectional traffic between the surface and interior of the cell and suggest that recycling of membrane components may take place from endocytic vesicles, lysosomes, as well as the Golgi complex.     

Lysosomal membrane proteins do not bind to mannose-6-phosphate-specific receptors

Lysosomal membrane proteins and soluble lysosomal material were isolated from pulse-chase labelled human skin fibroblasts and examined for incorporation of radioactivity and affinity to immobilized mannose-6-phosphate-specific receptors. Incorporation of radioactivity into lysosomal membrane proteins was delayed by about 2 h on average when compared to that of soluble lysosomal proteins. The lack of binding indicates that a mannose-6-phosphate-independent mechanism is responsible for targeting of lysosomal membrane proteins to lysosomes. In contrast to soluble lysosomal proteins, the membrane proteins did not bind to mannose-6-phosphate specific receptors. The delayed appearance of membrane proteins in lysosomes as compared to that of soluble lysosomal proteins suggested that different pathways are utilized by the two classes of lysosomal proteins.     

Lysosomal involvement in cellular turnover of plasma membrane sphingomyelin

At least two isoenzymes of sphingomyelinase (sphingomyelin cholinephosphohydrolase, EC 3.1.4.12), including lysosomal acid sphingomyelinase and nonlysosomal magnesium-dependent neutral sphingomyelinase, catalyse the degradation of sphingomyelin in cultured human skin fibroblasts. A genetically determined disorder of sphingomyelin metabolism, type A Niemann-Pick disease, is characterized by a deficiency of lysosomal acid sphingomyelinase. To investigate the involvement of lysosomes in the degradation of cellular membrane sphingomyelin, we have undertaken studies to compare the turnover of plasma membrane sphingomyelin in fibroblasts from a patient with type A Niemann-Pick disease, which completely lack acid sphingomyelinase activity but retain nonlysosomal neutral sphingomyelinase activity, with turnover in fibroblasts from normal individuals. Plasma membrane sphingomyelin was labeled by incubating cells at low temperature with phosphatidylcholine vesicles containing radioactive sphingomyelin. A fluorescent analog of sphingomyelin, N-4-nitrobenzo-2-oxa-1,3-diazoleaminocaproyl sphingosylphosphorylcholine (NBD-sphingomyelin) is seen to be readily transferred at low temperature from phosphatidylcholine liposomes to the plasma membranes of cultured human fibroblasts. Moreover, when kinetic studies were done in parallel, a constant ratio of [14C]oleoylsphingosylphosphorylcholine ( [14C]sphingomyelin) to NBD-sphingomyelin was taken up at low temperature by the fibroblast cells, suggesting that [14C]sphingomyelin undergoes a similar transfer. The comparison of sphingomyelin turnover at 37 degrees C in normal fibroblasts compared to Niemann-Pick diseased fibroblasts shows that a rapid turnover of plasma membrane-associated sphingomyelin within the first 30 min appears to be similar in both normal and Niemann-Pick diseased cells. This rapid turnover appears to be primarily due to rapid removal of the [14C]sphingomyelin from the cell surface into the incubation medium. During long-term incubation, an increase in the formation of [14C]ceramide correlating with the degradation of [14C]sphingomyelin is observed in normal fibroblasts. In contrast, the level of [14C]ceramide remains constant in Niemann-Pick diseased cells, which correlates with a higher level of intact [14C]sphingomyelin remaining in these cells compared to normal cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

Membrane shuttle between plasma membrane, phagosomes, and pinosomes in Dictyostelium discoideum amoeboid cells

The intracellular redistribution of membrane internalized during endocytosis was studied quantitatively by a biochemical approach and by a morphometric analysis of autoradiographs in electron microscopy. Plasma membrane glycoconjugates, enzymatically labelled with radioactive galactose, were used as a membrane marker. In cells labelled at their surface either before or after the phagocytotic uptake of latex beads, subsequent endocytosis led to a redistribution of label between the plasma membrane and endosomal membranes until a steady-state was reached after about 1 h with 43% of the label on the plasma membrane. The steady-state resulted when all participating membranes carried the same surface density of label. During phagocytosis or pinocytosis the equivalent of the plasma membrane was internalized and recycled once every 20 min or 40 min, respectively. Compared to this rate a very rapid and complete mixing of membranes was observed between newly formed phagosomes and preexisting digestive vacuoles or between newly formed pinosomes and preexisting phagosomes. Due to this rapid mixing, the membranes enclosing undigestible latex beads remained fully linked to the shuttle of membrane to and from the cell surface.     

Effect of chloroquine on the degradation of L-fucose and the polypeptide moiety of plasma membrane glycoproteins

To evaluate the role of lysosomes in the breakdown of the carbohydrate and the polypeptide moiety of plasma membrane glycoproteins, degradation of the plasma membrane glycoprotein gp120 was studied in the liver of rats treated with the lysosomotropic amine chloroquine. Half-lives of degradation of the terminal sugar L-fucose and of L-methionine of gp120 were measured in isolated plasma membranes after pulse-chase experiments in vivo. Chloroquine extended the plasma membrane half-life of the polypeptide moiety of gp120 from 51 h to 143 h. By contrast, L-fucose of gp120 in the plasma membrane was not affected by chloroquine, but decayed with the same short half-lives of 22 h and 23 h in both controls and chloroquine-treated rats. The data suggest that the protein portion of gp120 is degraded within the lysosomes. Conversely, the terminal sugar L-fucose is removed from the glycoprotein independent from proteolysis before segregation of the glycoprotein into the lysosomal compartment.     

Membrane proteins of the vacuolar system. III. Further studies on the composition and recycling of endocytic vacuole membrane in cultured macrophages

In previous publications (Muller, W.A., R.M. Steinman, Z.A. Cohn. 1980, J.Cell Biol. 86:292-314), we found that the membrane of macrophage phagolysosomes could be selectively radioiodinated in living cells, The technique required phagocytosis of lactoperoxidase covalently coupled to latex spheres (LPO-latex), followed by iodination on ice with Na(125)I and hydrogen peroxide. In this paper, we use the LPO-latex system to further analyze the composition and recycling of phagocytic vacuole membrane. Three approaches were employed to examine the polypeptide composition of the phagolysosome (PL) and plasma membranes (PM). (a) The efficiency of intracellular iodination was increased by increasing lysosomal pH with chloroquine. By one-dimensional SDS PAGE, the heavily labeled chloroquine-treated PL exhibited the same labeled polypeptides as PM iodinated extracellularly with LPO-latex. (b) Iodinated PL and PM were compared by two-dimensional gel electrophoresis. No differences in the isoelectric point and molecular weight of the major iodinated species were detected. (c) Quantitative immune precipitation was performed with five specific antibodies directed against cell surface antigens. Four antibodies precipitated similar relative amounts of labeled antigen on the cell surface and endocytic vacuole. One antibody, secreted by hybridoma 2.6, detected a 21-kdalton polypeptide that was enriched sevenfold in PL membrane. This enrichment was cell surface-derived, since the amount of labeled 2.6 was increased sevenfold when iodinated PM was driven into the cell during latex uptake. Therefore, intracellular iodination primarily detects PL proteins that are identical to their PM counterparts. Additional studies employed electron microscope autoradiography to monitor the centrifugal flow of radiolabeled polypeptides from PL to PM. Cells were iodinated intralysosomally and returned to culture for only 5-10 min at 37 degrees C. Most of the cell-associated label then redistributed to the cell surface or its adjacent area. Significant movement out of the lysosome compartment occurred even at 2 degrees C and 22 degrees C. Extensive and rapid membrane flow through the secondary lysosome presumably contributes to the great similarity between PM and PL membrane polypeptides.     

Intracellular localization and degradation of asialofetuin in isolated rat hepatocytes.

Analysis by isopycnic and differential centrifuging of the intracellular distribution of radioactivity following uptake of 125I-labelled asialofetuin by isolated rat hepatocytes showed that during incubations up to 1 h, most of the radioactivity was associated with structures which had a subcellular distribution pattern different from both the lysosomes and the plasma membrane. The latter two organelles were followed by means of enzyme markers. Ca2+ is necessary for the binding of asialofetuin to the plasma membrane, and it was also possible to differentiate between asialofetuin bound to the plasma membrane and that contained in intracellular structures by removing Ca2+ from the medium (by EGTA). Such experiments showed that asialofetuin became rapidly internalized. Practically all the labelled protein was located intracellularly in cells that had been incubated with asialofetuin for more than 30 min. When incubations were carried out for more than 1 h a peak appeared in the radioactivity distribution in the same place as the peak of activity of lysosomal marker enzymes. However, degradation of asialofetuin takes place in the lysosomes and this starts before the labelled protein can be found in the lysosomal fractions. Our data suggest that the rate-determining step in the cellular handling of asialofetuin is the transport of endocytized protein from the endocytic vesicles to the lysosomes.     

Externally disposed plasma membrane proteins. II. Metabolic fate of iodinated polypeptides of mouse L cells

The fate of the L-cell plasma membrane proteins labeled by enzymatic iodination was studied. The disappearance of label from growing cells exhibits a biphasic behavior, with 5-20% lost rapidly (t1/2 similar to 2 h) and 80-90% lost relatively slowly (t1/2 similar to 25-33 h). The loss is temperature dependent and serum independent, and is accompanied by the appearance of 51% (125-I)monoiodotyrosine (MIT) in the medium by 47 h. A variable amount (1-14%) of acid-insoluble label can be recovered in the medium over 47 h. Sodium dodecyl sulfate (SDS)-polyacrylamide gel labeling patterns from cells cultured up to 48 h after iodination reveal no change in the relative distribution of radioactivity, indicating similar rates of degradation for most of the labeled membrane proteins. The fate of the labeled membrane proteins was studied at various times after phagocytosis of nondigestible polystyrene particles. Iodinated L cells phagocytose sufficient 1.1 mum latex beads in 60 min to interiorize 15-30% of the total cell surface area. Electron microscope autoradiography confirmed that labeled membrane is internalized during phagocytosis. The latex-containing phagocytic vacuoles are isolated by flotation in a discontinuous sucrose gradient. 15-30% of the total incorporated label and a comparable percentage of alkaline phosphodiesterase I activity (PDase, a plasma membrane enzyme marker) are recovered in the phagocytic vacuole fraction. Lysosomal enzyme activities are found in the latex vacuole fraction, indicating formation of phagolysosomes. SDS gel analyses reveal that all of the radioactive proteins initially present on the intact cell's surface are interiorized to the same relative extent. Incorporated label and PDase activity disappear much more rapidly from the phagolysosomes than from the whole cell. In the phagolysosomal compartment, greater than 70% of the TCA-precipitable labeled proteins and all of the PDase activity are lost rapidly (t1/2 equals 1-2 h) but similar 30% of the labeled proteins in this compartment are degraded with a 17-20 h half-life. The slowly degraded label is due to specific long-lived polypeptides, of 85,000 and 8,000-15,000 daltons, which remain in the phagolysosomal membrane up to 40 h after phagocytosis.     

The membrane proteins of the vacuolar system. II. Bidirectional flow between secondary lysosomes and plasma membrane

Lactoperoxidase covalently coupled to latex spheres (LPO-latex) has been used to selectively iodinate the phagolysome (PL) membrane within living macrophages, as discussed in the accompanying article. This procedure labeled approximately 24 polypeptides in the PL membrane; these were similar to those iodinatable on the external surface of the plasma membrane (PM). We now report on the translocation and fate of these proteins when the cells are returned to culture. TCA-precipitable radioactivity was lost from cells with biphasic kinetics. 20-50% of the cell-associated radiolabel was rapidly digested (t 1/2 approximately equal to 1 h) and recovered in the culture medium as monoiodotyrosine. 50-80% of the label was lost slowly from cells ( 1/2 approximately equal to 24-30 h). Quantitative analysis of gel autoradiograms showed that all radiolabeled proteins were lost at the same rate in both the rapid and slow phases of digestion. Within 15-30 min aftr labeling of the PL membrane, EM autoradiography revealed that the majority of the cell-associated grains, which at time 0 were associated with PL, were now randomly dispersed over the plasmalemma. At this time, analysis of PM captured by a second phagocytic load revealed the presence of all labeled species originally present in the PL membrane. This demonstrated the rapid, synchronous centrifugal flow of PL polypeptides to the cell surface. Evidence was also obtained for the continuous influx of representative samples of the PM into the PL compartment by way of pinocytic vesicles. This was based on the constant flow of fluid phase markers into latex-containing PL and on the internalization of all iodinatable PM polypeptides into this locus. These observations provide evidence for the continuous, bidirectional flow of membrane polypeptides between the PM and the secondary lysosome and represent an example of a membrane flow and recycling mechanism.     

Biosynthesis of the glycoproteins present in plasma membrane, lysosomes and secretory materials, as visualized by radioautography

Synopsis The three major types of glycoproteins present in animal cells, that is, the secretory, lysosomal and plasma membrane glycoproteins, were examined with regard to the sites of synthesis of their carbohydrate side chains and to their subsequent migration within cells.The site at which a monosaccharide is added to a growing glycoprotein depends on the position of that monosaccharide in the carbohydrate side-chain. Thus, radiauutography of thyroid cells within minutes of the intravenous injection of labelled mannose, a sugar located near the base of the larger side-chains, reveals that it is incorporated in rough endoplasmic reticulum, whereas the more distally located galactose and fucose are incorporated in the Golgi apparatus. Recently [³H]N-acetylmannosamine, a specific precursor for the terminally located sialic acid residues, was shown to be also added in the Golgi apparatus. Presumably synthesis of glycoproteins is completed in this organelle.Radioautographs of animals sacrificed a few hours after injection of [³H]N-acetylmannosamine show that, in many secretory cells, labelled glycoproteins pass into secretory products. In these cells, as well as in non-secretory cells, the label may also appear within lysosomes and at the cell surface. In the latter site, it is presumably included within the plasma membrane glycoproteins whose carbohydrate side-chains form the cell coat. The continual migration of glycoproteins from Golgi apparatus to cell surface implies turnover of plasma membrane glycoproteins. Radioautographic quantitation of [³H]fucose label at the surface of proximal tubule cells in the kidney of singly-injected adult mice have shown that, after an initial peak, cell surface labelling decreases at a rate indicating a half-life of plasma membrane glycoproteins of about three days.     

Biochemical analysis of the movement of a major lysosomal membrane glycoprotein in the endocytic membrane system

HRP-anti LGP107Fab' and 125I-anti LGP107IgG were used as probes to study the movement of LGP107 in the endocytic membrane transport system in primary cultured hepatocytes of rats. Following the addition of HRP-anti LGP107Fab' to the culture medium, the transfer of the antibody conjugate from the cell surface of lysosomes was examined by cell fractionation on Percoll density gradients. The HRP tracer showed a bimodal subcellular distribution, in plasma membrane and lysosomal fractions. The amount of HRP found in the lysosomal fractions became larger as the period of cell incubation was increased. The rate of HRP accumulation in lysosomes was 0.13% of the administered load per hour per 10(6) cells. When cells were given 125I-anti LGP107 IgG, the antibody was not stored but was rapidly degraded in the lysosomes. The uptake of 125I-IgG by the cells, which was assessed by measuring the TCA-soluble radiolabeled degradation products released into the medium, increased proportionally to the administered concentration of the antibody and to the incubation time. The rate of uptake of the polyvalent 125I-IgG was comparable to that for the uptake of the monovalent HRP-Fab', and remained unchanged even after long exposure of the cells to a saturating concentration of the polyvalent IgG. This uptake process continued for many hours in the cells exposed to the protein synthesis inhibitor, cycloheximide. These results suggest that there is a continuous circulation of LGP107 between the cell surface and lysosomes in hepatocytes.     

O-(4-Diazo-3,5-di[125I]iodobenzoyl)sucrose, a novel radioactive label for determining organ sites of catabolism of plasma proteins.

A method is described for radiolabelling proteins with O-(4-diazo-3,5-di[125I]iodobenzoyl)sucrose (DD125IBS). When proteins so labelled were degraded within lysosomes, the radioactive fragments were largely retained within the organelle. High specific radioactivities were obtained without changing the properties of the protein. The validity of the method was demonstrated in vivo in rats using the short-lived protein lactate dehydrogenase, isoenzyme M4, and the long-lived protein bovine serum albumin. Derivatization with DD125IBS did not alter the clearance of either protein. Uptake of DD125IBS-labelled lactate dehydrogenase, isoenzyme M4, by liver and spleen of rats was determined. Radioactivity in these tissues increased up to about 2 h after injection (at this time the protein has been almost completely cleared from the blood) and subsequently declined with a half-life of approx. 20 h. After differential fractionation of liver, radioactivity was largely found in the mitochondrial and lysosomal fraction. The results of these studies establish that DD125IBS covalently coupled to plasma proteins should be a useful radioactive tracer for identifying the tissue and cellular sites of catabolism of relatively long-lived circulating proteins.