Receptor-mediated endocytosis in rat liver: purification and enzymic characterization of low density organelles involved in uptake of galactose-exposing proteins

Rat liver organelles involved in receptor-mediated endocytosis were labeled with a conjugate of galactosylated BSA to horseradish peroxidase [( 3H]galBSA-HRP), injected 10 min before sacrifice. These organelles were recovered at low density (1.11-1.13 g/ml) in sucrose gradients (Quintart, J., P. J. Courtoy, J. N. Limet, and P. Baudhuin, 1983, Eur. J. Biochem., 131:105-112). Upon incubation of such low density fractions in 3,3'-diaminobenzidine (DAB) and H2O2 and equilibration in a second sucrose gradient, galBSA-HRP-containing particles selectively shifted towards heavier densities (Courtoy, P. J., J. Quintart, and P. Baudhuin, 1984, J. Cell Biol., 98:870-876, companion paper), resulting in up to 250-to 300-fold purification with respect to the homogenate. The most purified preparations, wherein DAB- stained structures represented approximately 85% of the total volume of particles, contained only trace activities of enzymes usually regarded as markers for other subcellular entities. These minor activities could reflect either contamination or true enzyme association to the ligand- containing structures. Considering the latter hypothesis, at most 1.0% of alkaline phosphodiesterase I and 2.6% of 5'-nucleotidase (markers for plasma membrane), 3.6% of N-acetyl-beta-glucosaminidase (lysosomes), and 6.0% of galactosyltransferase (Golgi complex) from the homogenate would be associated with the whole population of ligand- containing organelles. After DAB cytochemistry on liver fixed 10 min after galBSA-HRP injection, ligand-containing structures accounted for 0.78-0.89% of the fractional volume of the hepatocytes and displayed a membrane area of 2,100 cm2/cm3, compared with 6,700 cm2/cm3 for the pericellular membrane. Altogether, our data support the hypothesis that these ligand-containing organelles are structurally distinct from plasma membrane, lysosomes, and Golgi complex.     

Sorting of endocytosed transferrin and asialoglycoprotein occurs immediately after internalization in HepG2 cells

After receptor-mediated uptake, asialoglycoproteins are routed to lysosomes, while transferrin is returned to the medium as apotransferrin. This sorting process was analyzed using 3,3'-diaminobenzidine (DAB) cytochemistry, followed by Percoll density gradient cell fractionation. A conjugate of asialoorosomucoid (ASOR) and horseradish peroxidase (HRP) was used as a ligand for the asialoglycoprotein receptor. Cells were incubated at 0 degree C in the presence of both 131I-transferrin and 125I-ASOR/HRP. Endocytosis of prebound 125I-ASOR/HRP and 131I-transferrin was monitored by cell fractionation on Percoll density gradients. Incubation of the cell homogenate in the presence of DAB and H2O2 before cell fractionation gave rise to a density shift of 125I-ASOR/HRP-containing vesicles due to HRP-catalyzed DAB polymerization. An identical change in density for 125I-transferrin and 125I-ASOR/HRP, induced by DAB cytochemistry, is taken as evidence for the concomitant presence of both ligands in the same compartment. At 37 degrees C, sorting of the two ligands occurred with a half-time of approximately 2 min, and was nearly completed within 10 min. The 125I-ASOR/HRP-induced shift of 131I-transferrin was completely dependent on the receptor-mediated uptake of 125I-ASOR/HRP in the same compartment. In the presence of a weak base (0.3 mM primaquine), the recycling of transferrin receptors was blocked. The cell surface transferrin receptor population was decreased within 6 min to 15% of its original size. DAB cytochemistry showed that sorting between endocytosed 131I-transferrin and 125I-ASOR/HRP was also blocked in the presence of primaquine. These results indicate that transferrin and asialoglycoprotein are taken up via the same compartments and that segregation of the transferrin-receptor complex and asialoglycoprotein occurs very efficiently soon after uptake.     

Intracellular pathway followed by invertase endocytosed by rat liver

Yeast invertase, when injected into rats, is endocytosed by the liver, mainly by sinusoidal cells. The work reported here aims at investigating the organelles involved in the intracellular journey of this protein. Experiments were performed on rats injected with 125I-invertase (25 micrograms/100 g body wt) and killed at various times after injection. Homogenates were fractioned by differential centrifugation, according to de Duve, Pressman, Gianetto, Wattiaux and Appelmans [(1955) Biochem. J. 63, 604-617]. Early after injection the radioactivity was recovered mainly in the microsomal fraction P; later it was found in the mitochondrial fractions (ML). At all times a peak of relative specific activity was observed in the light mitochondrial fraction L. After isopycnic centrifugation in a sucrose gradient, structures bearing 125I-invertase, present in P, exhibited a relatively flattened distribution with a density of around 1.17 g/ml, relatively similar to that of alkaline phosphodiesterase a plasma membrane marker. The organelles located in ML were endowed with a more homogeneous distribution, their median equilibrium density increasing up to 30 min after injection (1.20 g/ml----1.23 g/ml); with time the radioactivity distribution became more closely related to the distribution of arylsulfatase, a lysosomal enzyme. ML fractions, isolated 10 min and 180 min after 125I-invertase injection, were subjected to isopycnic centrifugation in Percoll gradient with, as solvent, 0.25 M, 0.5 M and 0.75 M sucrose. The change of density of the particles bearing 125I-invertase, as a function of the sucrose concentration, paralleled the change of density of the lysosomes as ascertained by the behaviour of arylsulfatase. The distribution of radioactivity and arylsulfatase in a sucrose gradient was established after isopycnic centrifugation of the ML fraction of rats injected with 125I-invertase, the animals having received or not an injection of 900 micrograms/100 g body weight of unlabelled invertase 15 h before killing. In agreement with our previous results, a shift towards higher densities of about 25% or arylsulfatase takes place in rats pretreated with unlabelled invertase. At 10 min, invertase preinjection did not change the radioactivity distribution curve. Later, it caused a progressive shift of the distribution towards higher-density regions of the gradient where the arylsulfatase, which had been shifted, was located.(ABSTRACT TRUNCATED AT 400 WORDS)     

Biochemical evidence for an endocytically inactive population of lysosomes

The peroxidase dependent, diaminobenzidine (DAB) density shift procedure was applied to the characterization of lysosomes from Chinese hamster ovary (CHO) cells. Peroxidase activity was localized in lysosomes by a 15-18 h internalization period. After treatment with DAB, the distribution of peroxidase activity in Percoll gradients was shifted, as a population, to a higher density. A bimodal distribution which included a low density population was observed for the native lysosomal enzyme beta-hexosaminidase after DAB treatment. A second lysosomal enzyme, alpha-fucosidase, was strongly inhibited by DAB treatment with the residual activity corresponding in distribution to the light beta-hexosaminidase population. The occurrence of a low density lysosomal population after the DAB procedure suggests the existence of an endocytically inactive lysosomal population in fibroblasts. Probable physiological candidates for such a population are discussed.     

Intracellular routing of GLcNAc-bearing molecules in thyrocytes: selective recycling through the Golgi apparatus

Previous experiments led us to speculate that thyrocytes contain a recycling system for GlcNAc-bearing immature thyroglobulin molecules which prevents these molecules from lysosomal degradation (Miquelis, R., C. Alquier, and M. Monsigny. 1987. J. Biol. Chem. 262:15291-15298). To confirm this hypothesis, the fate of GlcNAc-bearing proteins after internalization by thyrocytes was monitored and compared to that of fluid phase markers. Kinetic internalization studies were performed using 125I-GlcNAc-BSA and 131I-Man-BSA. We observed that the apparent intake rate as well as the amount of hydrolyzed GlcNAc-BSA are smaller than the corresponding values for Man-BSA. These differences were reduced by GlcNAc competitors (thyroglobulin and ovomucoid) or a weak base (chloroquine). Part of the internalized GlcNAc-BSA was released into the extracellular milieu at a higher rate and shorter half life (t1/2 = approximately 30 min) than the Man-BSA (t1/2 = approximately 8 h). Subcellular homing was first studied by cell fractionation after internalization using 125I-ovomucoid and 131I-BSA. During Percoll density gradient fractionation, endogenous thyroperoxidase was used to separate subsets of organelles involved in the biosynthetic exocytotic pathway. Incubation of the cell homogenate in the presence of DAB and H2O2 before cell fractionation give rise to a shift in the density of organelles containing 3.5 times more ovomucoid than BSA. Discontinuous sucrose gradient showed that: (a) thyroperoxidase was colocalized with galactosyltransferase-contraining organelles in Golgi-rich subfractions; and (b) that at every time studied from 10 to 100 min, the ovomucoid/BSA ratio was higher in these organelles than in other subfractions. Finally we also observed that: (a) ovomucoid sequestered in the Golgi-rich subfraction incorporated [3H]galactose; and (b) that part of internalized ovomucoid was localized on the Golgi stacks as well as elements of the trans-Golgi, as revealed by immunogold labeling on ultrathin cryosections. These data prove that in thyrocytes GlcNAc accessible sugar moieties on soluble internalized molecules are sufficient to trigger their recycling via the Golgi apparatus.     

The pathways of endocytosed transferrin and secretory protein are connected in the trans-Golgi reticulum

We used a conjugate of transferrin and horseradish peroxidase (Tf/HRP) to label the intracellular transferrin receptor route in the human hepatoma cell line HepG2. The recycling kinetics of [125I]Tf/HRP were similar to those of unmodified [125I]Tf, implying identical routes for both ligands. 3,3'Diaminobenzidine (DAB)-cytochemistry was performed on post-nuclear supernatants of homogenates of cells which were incubated with both Tf/HRP and [125I]Tf, and caused two different effects: (a) the equilibrium density of [125I]Tf containing microsomes in a Percoll density gradient was increased, and (b) the amount of immunoprecipitable [125I]Tf from density-shifted lysed microsomes was only 20% of that of nonDAB treated microsomes. The whole biosynthetic route of alpha 1-antitrypsin (AT), a typical secretory glycoprotein in HepG2 cells, was labeled during a 60-min incubation with [35S]methionine. DAB cytochemistry was performed on post-nuclear supernatants of homogenates of cells which were also incubated with Tf/HRP. DAB cytochemistry caused approximately 40% of microsome- associated "complex" glycosylated [35S]alpha 1-antitrypsin ([35S]c-AT) to shift in a Percoll density gradient. Only part of the density shifted [35S]c-AT could be recovered by immunoprecipitation. A maximum effect was measured already after 10 min of Tf/HRP uptake. The density distribution of the "high mannose" glycosylated form of 35S-alpha 1- anti-trypsin [( 35S]hm-AT) was not affected by Tf/HRP. If in addition to Tf/HRP also an excess of non-conjugated transferrin was present in the medium, [35S]c-AT was not accessible for Tf/HRP, showing the involvement of the transferrin receptor (TfR) in the process. Furthermore, we show that if Tf/HRP and [35S]c-AT were located in different vesicles, the density distribution of [35S]c-AT was not affected by DAB-cytochemistry. Pulse-labeling with [35S]methionine was used to show that [35S]c-AT became accessible to endocytosed Tf/HRP minutes after acquirement of the complex configuration. A common intracellular localization of endocytosed Tf/HRP and secretory protein could be confirmed by immuno-electron microscopy: cryosections labeled with anti-albumin (protein A-colloidal gold) as well as DAB reaction product showed double-labeling in the trans-Golgi reticulum.     

Intracellular localization of heat shock proteins in maize

The intracellular distribution of the maize root heat shock proteins (hsp) was studied as a step toward understanding their physiological function. Linear sucrose density centrifugation was employed to separate organelles so the relative quantities of hsp in different subcellular compartments could be analyzed in a single preparation. Gradient fractions were assayed for the presence of hsp by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and for marker enzyme activities. Analyses of 15 to 60% gradients showed five hsp to be organelle associated. Hsp 25 and 72 were in fractions containing closely equilibrating Golgi and endoplasmic reticulum marker activities, while hsp 18, 29, and 72 were in fractions containing overlapping plasma membrane, mitochondria, and glyoxysomal marker activities. Hsp larger than 72 kilodaltons were not present in gradient fractions. A second fractionation scheme achieved better separation of the two sets of closely equilibrating organelles. When a 13,000g centrifugation step to remove mitochondria was employed prior to gradient centrifugation, hsp 29 was absent from the gradient fractions. If the buoyant density of the endoplasmic reticulum was shifted by either maintaining the ribosomes on the membrane or removing them, a corresponding shift in the equilibrium positions of hsp 25 and 72 occurred. Hsp 18 and 70 remained in plasma membrane-containing fractions irrespective of these treatments.     

The small GTP-binding protein Rho1p is localized on the Golgi apparatus and post-Golgi vesicles in Saccharomyces cerevisiae

In Saccharomyces cerevisiae the ras-related protein Rho1p is essentially the only target for ADP-ribosylation by exoenzyme C3 of Clostridium botulinum. Using C3 to detect Rho1p in subcellular fractions, Rho1p was found primarily in the 10,000 g pellet (P2) containing large organelles; small amounts also were detected in the 100,000 g pellet (P3), and cytosol. When P2 organelles were separated in sucrose density gradients Rho1p comigrated with the Kex-2 activity, a late Golgi marker. Rho1p distribution was shifted from P2 to P3 in several mutants that accumulate post-Golgi vesicles. Rho1p comigrated with post-Golgi transport vesicles during fractionation of P3 organelles from wild-type or sec6 cells. Vesicles containing Rho1p were of the same size but different density than those bearing Sec4p, a ras-related protein located both on post-Golgi vesicles and the plasma membrane. Immunofluorescence microscopy detected Rho1p as a punctate pattern, with signal concentrated towards the cell periphery and in the bud. Thus, in S. cerevisiae Rho1p resides primarily in the Golgi apparatus, and also in vesicles that are likely to be early post-Golgi vesicles.     

Subcellular distribution of leukotriene C4 binding units in cultured bovine aortic endothelial cells

The subcellular distribution of specific binding sites for [3H]leukotriene C4 ([3H]LTC4) was analyzed after sedimentation of organelles from disrupted bovine aortic endothelial cells on sucrose density gradients and was shown to be in membrane fractions I (20% sucrose) and IV (35% sucrose). Saturation binding studies of [3H]LTC4 on endothelial cell monolayers at 4 degrees C demonstrated high-affinity binding sites with a dissociation constant (Kd) of 6.8 +/- 2.2 nM (mean +/- SD) and a density of 0.12 +/- 0.02 pmol/10(6) cells. At 4 degrees C, the specific binding of [3H]LTC4 by each of the subcellular fractions reached equilibrium at 30 min and remained stable for an additional 60 min. After 30 min of incubation with [3H]LTC4, the addition of excess unlabeled LTC4 to each subcellular fraction reversed more than 70% of [3H]LTC4 binding in 10 min. The [3H]LTC4 binding activities of subcellular fractions were enhanced approximately twofold to fourfold in the presence of Ca2+, Mg2+, and Mn2+, whereas Na+, K+, and Li+ were without effect. As measured by saturation experiments, the Kd and density of LTC4 binding sites in fraction I were 4.8 +/- 1.6 nM and 16.5 +/- 1.9 pmol/mg of protein, respectively, and in fraction IV were 4.7 +/- 1.5 nM and 81.4 +/- 19 pmol/mg of protein, respectively. Inhibition of [3H]LTC4 binding in membrane-enriched subcellular fractions I and IV by LTC4 occurred with molar inhibition constant (Ki) values of 4.5 +/- 0.1 nM and 4.7 +/- 1.2 nM, respectively, whereas Ki values for LTD4 were 570 +/- 330 nM and 62.5 +/- 32.8 nM, respectively, and for LTE4 were greater than 1000 nM for each fraction; LTB4 and reduced glutathione were even less active. FPL55712, a putative antagonist of the sulfidopeptide LT components of slow reacting substance of anaphylaxis, had Ki values of 1520 +/- 800 nM and 1180 +/- 720 nM for [3H]LTC4 binding sites on membrane-enriched subcellular fractions I and IV, respectively. Thus as defined by Kd, Ki, and specificity, the LTC4 binding units that are distributed to the plasma membrane and the binding units in the subcellular fraction of greater density were similar to each other. Pretreatment of the isolated subcellular membrane fractions with trypsin abolished [3H]LTC4 binding by fraction I, enriched for the plasma membrane marker 5' nucleotidase, and that by fraction IV, enriched for the mitochondrial membrane marker succinate-cytochrome C reductase.(ABSTRACT TRUNCATED AT 400 WORDS)     

Effect of acute ethanolic intoxication on the neuraminidase activity of rat liver golgi apparatus

Neuraminidase and galactosyltransferase were investigated in total Golgi apparatus and in the three fractions of increasing densities (GF₁, GF₂ and GF₂) isolated from the microsomal fraction of rat liver homogenates by flotation in a discontinuous sucrose density gradient (Ehrenreich, J.H., Bergeron, J.J.M., Siekevitz, P. and Palade, G.E. (1973) J. Cell Biol. 59, 45–72). About 50% decreases in neuraminidase content (units/g liver) and specifixc activity (units/ mg protein) were observed in total Golgi as well as in the three fractions isolated at 45 min, 90 min, 180 min and 16 h after administration of a single oral dose of 50% aqueous ethanol (0.6 g/100 g body weight). Colchicine administration (intraperitoneal injection, 0.5 mg/100 g body weight) caused a similar loss of neuraminidase activity; however, the effect of ethanol plus colchicine was not additive. Golgi galactosyltransferase, on the other hand, experienced marked increases of activity following ethanol administration but, unlike the results reported by others (Gang, H., Lieber, C.S. and Rubin, E. (1973) Nat. New Biol. 243, 123–125), significant increases in total activity and specific activity were already quite evident at 90 min after ethanol ingestion. In contrast with the decreased values observed in Golgi, the total particle-bound neuraminidase was significantly elevated following ethanol administration. Ultrastructural studies revealed increased lysosomal content and detachment of polysomes from the rough endoplasmic reticulum. A model, which takes into account these enzymological and ultrastructural findings and their biological significance, is proposed.     

Nicotinamide cofactors (NAD and NADP) in glyoxysomes,mitochondria, and plastids isolated from castor bean endosperm

Glyoxysomes, mitochondria, and plastids were separated from the cytosol of germinating castor bean endosperm by sucrose gradient centrifugation in a vertical rotor (25 min, 50,000g_av). The amounts of nicotinamide cofactors, NAD(H) and NADP(H), retained in the isolated organelle fractions were measured by enzyme cycling techniques. The NAD(H) was equally distributed between the cytosol and the mitochondria with a small amount in the glyoxysomes. The mitochondria retained 4 pmol of NAD(H)/ μg protein, about seven times as much as the glyoxysomes. Most of the NADP(H) was in the cytosol. However, the glyoxysomes and plastids retained significant amounts, both having 0.3 pmol NADP(H)/μg protein, twice that in the mitochondria. The subcellular distribution of NADP(H) was compared to the location of dehydrogenases capable of using this cofactor. The cytosol and plastids contained 6-phosphogluconate dehydrogenase. NADP isocitrate dehydrogenase was found in the glyoxysomes, in mitochondria, and in an unidentified subcellular fraction obtained at 1.16 g/ml in the density gradients. Knowledge of the quantities of NADP(H) and NAD(H) retained in the isolated organelles should make it possible to investigate their reduction and reoxidation in intact organelles.     

Characterization of rabbit lung lysosomes and their role in surfactant dipalmitoylphosphatidylcholine catabolism

Although alveolar surfactant is rapidly catabolized in adult rabbit lungs, the pathways have not been characterized. Pathways of surfactant secretion and recycling involve lamellar bodies and multivesicular bodies, organelles shown to be related to lysosomes by cytochemistry and autoradiography. Since lysosomes are central to intracellular catabolic events, it is possible that lysosomes are involved in intrapulmonary surfactant catabolism. Lysosomes relatively free of contaminating organelles (as determined morphologically and by marker enzymes for mitochondria, endoplasmic reticulum, peroxisomes, and plasma membranes) were obtained from post-lavage lung homogenates of 1-kg rabbits by differential centrifugation in buffered sucrose and gradient separation in percoll (density, 1.075-1.165). The role of lung lysosomes in catabolism of dipalmitoylphosphatidylcholine (DPC) was then studied in rabbits killed 4, 12, and 24 h following intratracheal injection of [3H]DPC and [14C] dihexadecyl phosphatidylcholine (DPC-ether). While equal amounts of label were in the lamellar body containing fractions at 4 h, nearly 6-fold more DPC-ether label than DPC label was recovered in the lysosomal fractions. By 24 h, there was 15-fold more DPC-ether in the lysosomes. This is the first report of successful isolation of lysosomes relatively free of other organelles from rabbit lungs. The tracer studies indicate DPC and DPC-ether follow similar intracellular processing after alveolar uptake. The subsequent accumulation of the ether analog in the lysosomal fractions supports a role for these organelles in surfactant DPC catabolism.     

Uptake and intracellular transport in rat liver of formaldehyde-treated bovine serum albumin labelled with 125I-tyramine-cellobiose

1. Endocytosis of formaldehyde-treated bovine serum albumin by rat liver sinusoidal cells has been followed by injecting rats with the protein labelled with 125I-tyramine cellobiose (125I-TCfBSA). 125I-TCfBSA is quickly taken up by the liver; the radioactivity present in the organ reaches a plateau 5-10 min after injection and is maintained for up to at least 180 min. During the first 5 min most of radioactivity remains acid-precipitable. After which, labelled acid-soluble components are produced at a constant rate for up to 30-40 min. 2. Differential centrifugation shows that radioactivity is first recovered mainly in the microsomal fraction. Within a few minutes it exhibits a distribution pattern similar to that of lysosomal enzymes, being chiefly located in the mitochondrial fractions. 3. Isopycnic centrifugation in a sucrose gradient of the microsomal fraction isolated 1 min after injection indicates a similar distribution for radioactivity and alkaline phosphodiesterase. Later, the microsomal radioactivity distribution curve is shifted towards higher densities and becomes distinct from that of the plasma-membrane enzyme. After isopycnic centrifugation in a sucrose gradient of the total mitochondrial fraction a considerable overlapping of acid-precipitable and acid-soluble radioactivity distributions is observed without significant changes with time. The same is observed in a Percoll gradient except that after a relatively long time (greater than 30 min) of injection a marked shift of radioactivity distribution towards higher densities occurs. 4. A pretreatment of rats with Triton WR 1339, a density perturbant of liver lysosomes, causes a striking shift of acid-soluble radioactivity distribution in a sucrose gradient towards lower densities while having markedly less influence on the acid-precipitable distribution. As a result, a distinction between the distribution of both kinds of radioactivity becomes clearly apparent. A preinjection of yeast invertase, modifies the acid-soluble distribution without having a significant effect on the acid-precipitable distribution up to 30 min after 125I-TCfBSA injection. 5. Glycyl-1-phenylalanine-2-naphthylamide largely releases acid-soluble radioactivity associated with the mitochondrial fraction, whatever the time after 125I-TCfBSA injection. On the other hand the proportion of acid-precipitable radioactivity present in the fraction that can be released is almost zero at 10 min after injection, and it later increases. 6. The results presented here are best explained by supposing that, after being trapped in small pinocytic vesicles, 125I-TCfBSA is quickly delivered to the endosomes.(ABSTRACT TRUNCATED AT 400 WORDS)     

Intrahepatocellular site of the catabolism of heme and globin moiety of hemoglobin-haptoglobin after intravenous administration to rats

The intracellular site of incorporation and degradation of heme and globin moiety of hemoglobin-haptoglobin in rat liver cells was investigated in vivo. Hemoglobin-haptoglobin, administered intravenously to rats, is cleared from the circulation and incorporated exclusively into liver parenchymal cells through the receptor specific for the molecule (Kino, K., Tsunoo, H., Higa, Y., Takami, M., Hamaguchi, H., and Nakajima, H. (1980) J. Biol. Chem. 255, 9616-9620). Intracellular distribution of radioactivity was determined after intravenous administration of [3H-Heme,14C-Globin]hemoglobin-haptoglobin to rats. The doubly labeled hemoglobin-haptoglobin was incorporated first in organelles of lower anodic mobility in carrier-free electrophoresis and of low density (density range, 1.05-1.07 g/ml) in Percoll density gradient centrifugation recovered in Golgi subfractions of the liver cells in a substantially intact form. In the subsequent stages, these organelles progressively acquired a higher anodic mobility as well as higher density, presumably through fusion with other organelles. In the resulting organelles of higher anodic mobility in electrophoresis and high density (density range, 1.07-1.15 g/ml) in Percoll, the hemoglobin-haptoglobin first dissociated symmetrically into two 82,000-dalton subunits having intact heme, and then the organelles containing only 3H radioactivity but no 14C radioactivity were separated by electrophoresis. Most of the 3H radioactive materials in these organelles are identified as intact [3H]heme. These investigations suggest that the heme moiety of hemoglobin-haptoglobin in the organelles is detached from globin-haptoglobin and binds to another carrier protein prior to conversion of heme to bilirubin.     

Plasmodium falciparum: discovery of peroxidase active organelles

Staining with 3,3' diaminobenzidine tetrahydrochloride (DAB) is a common method used for the detection of peroxidases. Using this histochemical staining method in conjunction with transmission electron microscopy, we observed oxidation of DAB that was localized to a discrete set of organelles displaying morphological similarity to small (75-90 nm diameter) versions of higher eukaryotic microbodies or peroxisomes. These single membrane bounded organelles were characterized by an asymmetrical matrix capable of oxidizing DAB to an electron dense inclusion. Oxidation of DAB was further found to be dependent upon hydrogen peroxide (H2O2) as a substrate. Given a lack of peroxisomal import proteins and enzymes, it is unlikely that these represent conventional peroxisomes. Rather, they likely represent specialized organelles containing endogenous peroxidase or pseudo-peroxidase activity.     

Analytical subcellular fractionation of needle-biopsy specimens from human liver.

1. Fragments (2-20 mg wet wt.) of closed needle-biopsy specimens from human liver were disrupted in iso-osmotic sucrose and subjected to low-speed centrifugation. The supernatant was layered on a linear sucrose-density gradient in the Beaufay small-volume automatic zonal rotor. The following organelles, with equilibrium densities (g/ml) and principal marker enzyme shown in parentheses, were resolved: plasma membrane (1.12-1.14; 5'-nucleotidase); lysosomes (1.15-1.20; N-acetyl-beta-glucosaminidase); mitochondria (1.20; malate dehydrogenase); endoplasmic reticulum (1.17-1.21; neutral alpha-glucosidase); peroxisomes (1.22-1.24; catalase). 2. The distribution of particulate alkaline phosphatase and, to a lesser degree, leucine 2-naphthylamidase followed that of 5'-nucleotidase. gamma-Glutamyltransferase was associated with membranes of significantly higher equilibrium density than was 5'-nucleotidase. 3. The distribution of 12 acid hydrolases was determined in the density-gradient fractions. beta-Glucosidase had a predominantly cytosolic localization, but the other enzymes showed a broad distribution of activity throughout the gradient. Evidence was presented for two populations of lysosomes with equilibrium densities of 1.15 and 1.20 g/ml, but containing differing amounts of each enzyme. Further evidence of lysosomal heterogeneity was demonstrated by studying the distribution of isoenzymes of hexosaminidase and of acid phosphatase. 4. The resolving power of the centrifugation procedure can be further enhanced with membrane perturbants. Digitonin (0.12 mM) selectively disrupted lysosomes, markedly increased the equilibrium density of plasma-membrane components and lowered the density of the endoplasmic reticulum, but did not affect the mitochondria or peroxisomes. Pyrophosphate (15 mM) selectively lowered the equilibrium density of the endoplasmic reticulum.     

Morphological changes in Escherichia coli cells exposed to low or high concentrations of hydrogen peroxide

Escherichia coli cells challenged with low or high concentrations of hydrogen peroxide are killed via two different mechanisms and respond with morphological changes which are also dependent on the extracellular concentration of the oxidant. Treatment with low concentrations (less than 2.5 mM) of H2O2 is followed by an extensive cell filamentation which is dependent on the level of H2O2 or the time of exposure. In particular, addition of 1.75 mM H2O2 results in a growth lag of approximately 90 min followed by partial increase in optical density, which was mainly due to the onset of the filamentous response. In fact, microscopic analysis of the samples obtained from cultures incubated with the oxidant for various time intervals has revealed that this change in morphology becomes apparent after 90 min of exposure to H2O2 and that the length of the filaments gradually increases following longer time intervals. Analysis of the ability of these cells to form colonies has indicated a loss in viability in the first 90 min of exposure followed by a gradual recovery in the number of cells capable of forming colonies. Measurement of lactate dehydrogenase in culture medium (as a marker for membrane damage) has revealed that a small amount of this enzyme was released from the cells at early times (less than 150 min) but not after longer incubation periods (300 min). Cells exposed to high concentrations of H2O2 (greater than 10 mM) do not filament and their loss of viability is associated with a marked reduction in cell volume. In fact, treatment with 17.5 mM H2O2 resulted in a time-dependent decrease of the optical density, clonogenicity, and cellular volume. In addition, these effects were paralleled by a significant release in the culture medium of lactate dehydrogenase thus suggesting that the reduced cell volume may be dependent on membrane damage followed by loss of intracellular material. This hypothesis is supported by preliminary results obtained in electron microscopy studies. In conclusion, this study further demonstrates that the response of E. coli to hydrogen peroxide is highly dependent on the concentration of H2O2 and further stresses the point that low or high concentrations of the oxidant result in the production of different species leading to cell death via two different mechanisms and/or capable of specifically affecting the cell shape.     

Acute in vivo stimulation of low-Km cyclic AMP phosphodiesterase activity by insulin in rat-liver Golgi fractions

A low-Km phosphodiesterase activity, which is acutely stimulated by insulin in vivo, has been identified in plasma membranes and Golgi fractions prepared from rat liver homogenates in isotonic sucrose. Within seconds after insulin injection (25 micrograms/100 g body weight) cAMP phosphodiesterase activity increases by 30-60% in Golgi fractions and by 25% in plasma membranes; activity in crude particulate and microsomal fractions is unaffected. The increase in activity is short-lived in the light and intermediate Golgi fractions, but persists for at least 10 min in the heavy Golgi fraction. It precedes the translocation of insulin and insulin receptors to these fractions, which is maximal at 5 min. The doses of insulin required for half-maximal and maximal activation are, respectively, 7.5 micrograms/100 g and 25 micrograms/100 g body weight. Golgi-associated cAMP phosphodiesterase activity shows non-linear kinetics; a high-affinity component (Vmax, 13 pmol min-1 mg protein-1; Km, 0.35 microM) is detectable. Insulin treatment increases the Vmax 60-70%, but does not affect the Km. Unlike the low-Km cAMP phosphodiesterase associated with crude particulate fractions, the Golgi-associated activity is not easily extractable by solutions of low or high ionic strength. On analytical sucrose density gradients, low-Km cAMP phosphodiesterase associated with the total particulate fraction equilibrates at lower densities than endoplasmic reticulum and lysosomal markers, but at a higher densities than plasma membrane, Golgi markers and insulin receptors. Insulin treatment increases the specific activity of the enzyme by 20-60% at densities below 1.12 g cm-3, and by 20-40% in the density interval 1.23-1.25 g cm-3. Such treatment also causes a slight, but significant shift in the distribution of phosphodiesterase towards lower densities. It is suggested that Golgi elements or physically similar subcellular structures are a major site of localization of insulin-sensitive cAMP phosphodiesterase in rat liver. However, internalization of the insulin-receptor complex is probably not required for enzyme activation.     

Receptor-mediated endocytosis of polymeric IgA and galactosylated serum albumin in rat liver. Evidence for intracellular ligand sorting and identification of distinct endosomal compartments

Rat polymeric IgA (pIgA) and galactosylated bovine serum albumin (GalBSA), once injected to rats, are avidly taken up by hepatocytes via receptor-mediated endocytosis. Of injected pIgA, 64% was transferred undigested into bile within 3 h, with a peak at 30-45 min. GalBSA was essentially digested in lysosomes. By electron microscopy using ligand-peroxidase conjugates, both ligands were internalized through coated pits/coated vesicles into similar electron-lucent vesicles and tubules. Subsequently, pIgA remained mostly associated with small vesicles clustering around and fusing with bile canaliculi, while GalBSA was predominantly found in large, heterogeneous endocytic structures and in lysosomes. By subcellular fractionation, they were associated at 3 min after injection with structures that similarly sedimented in the P fraction (250 000 - 3 X 10(6) X g X min) and equilibrated at densities of about 1.13 g/ml in sucrose gradients. At 10 min and 20 min, pIgA distribution remained mostly in the P fraction at the same equilibrium density. A minor component of the pIgA distribution was found at the density of lysosomes, but contrary to lysosomal enzymes, its distribution was not affected by Triton WR 1339. In contrast to pIgA, GalBSA was progressively recovered in the L fraction (33 000 - 250 000 X g X min) with organelles equilibrating around 1.11 g/ml, and, by 20-45 min, was found in the ML fraction (10 000 - 250 000 X g X min), around 1.20 g/ml, i.e. in lysosomes. Chloroquine did not reduce the efficiency but delayed the secretion of pIgA into bile. Similarly, it did not affect the uptake of GalBSA but apparently delayed GalBSA transfer along successive populations of host organelles. The low density, GalBSA-containing structures were devoid of proteolytic activity. Anti-secretory components IgG and F(ab')2 were selectively excreted into bile, partially or totally as compounds of lower molecular mass. These antibody fragments probably result from a disulfide reduction activity along the pIgA pathway. In conclusion, our data (a) strongly suggest that pIgA and GalBSA are sorted between 3 min and 10 min after injection in non-lysosomal acidic organelles, (b) identify two successive and physically distinct endosomal populations containing GalBSA, and (c) provide the first evidence for a disulfide reduction activity along the transcytotic pathway of rat hepatocytes.     

Kinetic analysis of blood-brain barrier transport of amino acids.

The Michaelis-Menten kinetics of blood-brain barrier transport of fourteen amino acids was investigated with a tissue-sampling, single-injection technique in the anesthetized rat. Tracer quantities of 14C-labelled amino acids and 3H2O, used as a freely diffusible internal reference, were mixed in 0.2 ml of buffered Ringer's solution and injected rapidly into a common carotid artery. Circulation was terminated by decapitation at 15s following injection. A brain uptake index (Ib) was determined from the ratio of 14C dpm in the brain tissue and the injection mixture divided by the same ratio for the 3H2O reference. Brain clearance of tracer concentration of amino acid was saturable when various concentrations of unlabeled amino acid were added to the injection solution. Double reciprocal plots of the saturation data yielded Km (mM) values that ranged from a low of 0.09 mM for arginine to a high of 0.75 mM for cycloleucine. Transport V values were determined from the relationship P = V/Km where P is the blood-brain barrier permeability constant (ml/g per min): P was calculated from the Ib for each amino acid based on a cerebral blood flow of 0.56 ml/g per min and a fractional extraction of 0.75 for the 3H2O reference 15s following carotid injection. The V values ranged from a low of 6.2 nmol/g per min for lysine to a high of 64 nmol/g per min for l-DOPA. Efflux of the tracer amino acid during the 15-s period after injection was assumed to be slow, since the rate constant of cycloleucine from brain to blood was low, 0.11 min-1.