The fate of the N-formyl-chemotactic peptide receptor in stimulated human granulocytes: subcellular fractionation studies

Experiments were performed to examine how human granulocytes, stimulated by N-formyl-chemotactic peptides, process the N-formyl peptide receptor. One percent of the surface N-formyl-chemotactic peptide receptors of purified human granulocytes were covalently, specifically, and radioactively labeled at 4 degrees C using the photochemically reactive N-formyl-chemotactic hexapeptide CHO-Nle-Leu-Phe-Nle-[125I] Tyr-N epsilon (6-(4'-azido-2'-nitrophenyl-amino)hexanoyl)-Lys. After incubation in the presence of 500 nM of N-formyl-Met-Leu-Phe at 37 degrees C, the cells were lysed and fractionated by isopycnic surcrose density gradient sedimentation. Receptor-associated radioactivity cosedimented with plasma membrane in fractions from cells kept at 4 degrees C or incubated at 37 degrees C for 2 min or less. Fractionation of cells incubated at 37 degrees C for longer times revealed that the radioactivity sedimented to lower densities coincident with Golgi markers and the site of noncovalently bound and internalized formyl-chemotactic peptide. To follow the redistribution of unoccupied receptors, human granulocytes were stimulated with 500 nM N-formyl-Met-Leu-Phe at 37 degrees C for 5 min, washed, lysed by N2 cavitation, and fractionated by rate zonal sucrose density gradient sedimentation. Compared to unstimulated controls the specific binding of N-formyl-Met-Leu-[3H]Phe decreased 76% +/- 9% in plasma membrane fractions. N-formyl-Met-Leu-[3H]Phe-binding activity associated with an intracellular pool cosedimenting with specific granules remained unchanged. Approximately 20% of the activity lost in the plasma membrane could be accounted for by a redistribution of specific N-formyl-Met-Leu-Phe binding to fractions enriched in azurophil granules. We conclude that the receptor is the carrier in the internalization of the N-formyl-chemotactic peptides to a Golgi-enriched fraction and hypothesize that after a short residency in this fraction, the receptor may dissociate from the ligand and pass onto a fraction cosedimenting with dense granules.     

Fate of injected 125I-labeled cholera toxin taken up by rat liver in vivo. Generation of the active A1 peptide in the endosomal compartment

Subcellular fractionation techniques have been used to assess the localization of injected 125I-labeled cholera toxin (125I-CT) taken up by rat liver in vivo, and to determine whether internalization of the toxin is required for the generation of the active A1 peptide. The uptake of injected 125I-CT into the liver is maximal at 5 min (about 10% injected dose/g). At this time the radioactivity is for the most part recovered in the microsomal (P) fraction, but later on it progressively associates with the mitochondrial-lysosomal (ML) and supernatant fractions. The radioactivity is enriched 7-fold in plasma membranes at 5-15 min, and 15-60-fold in Golgi-endosome (GE) fractions at 15-60 min. On analytical sucrose gradients the radioactivity associated with the P fraction is progressively displaced from the region of 5'-nucleotidase (a plasma membrane marker) to that of galactosyltransferase (a Golgi marker). On Percoll gradients, however, it is displaced towards acid phosphatase (a lysosomal marker). Density-shift experiments, using Triton WR 1339, suggest that some radioactivity associated with the P fraction (at 30 min) and all the radioactivity present in the ML fraction (at 2 h) is intrinsic to acid-phosphatase-containing structures, presumably lysosomes. Comparable experiments using 3,3'-diaminobenzidine cytochemistry indicate that the radioactivity present in GE fractions is separable from galactosyltransferase, and thus is presumably associated with endosomes. The fate of injected 125I-labeled cholera toxin B subunit differs from that of the whole toxin by a more rapid uptake (and/or clearance) of the ligand into subcellular fractions, and a greater accumulation of ligand in the ML fraction. Analysis of GE fractions by SDS/polyacrylamide gel electrophoresis shows that, up to 10 min after injection of 125I-CT, about 80% of the radioactivity is recovered as A subunit and 20% as B subunit, similarly to control toxin. Later on there is a time-dependent decrease in the amount of A subunit and, at least with the intermediate GE fraction, a concomitant appearance of A1 peptide (about 15% of the total at 60 min). In contrast the radioactivity associated with plasma membranes remains indistinguishable from unused toxin. It is concluded that, upon interaction with hepatocytes, 125I-CT (both subunits A and B) sequentially associates with plasma membranes, endosomes and lysosomes, and that endosomes may represent the major subcellular site at which the A1 peptide is generated.     

Subcellular distribution of alpha 1-adrenergic receptors in rat liver

The distribution of alpha 1-adrenergic receptors in rat liver subcellular fractions was studied using the alpha 1-adrenergic receptor ligand [3H]prazosin. The highest number of [3H]prazosin binding sites was found in a plasma membrane fraction followed by 2 Golgi and a residual microsomal fraction, the numbers of binding sites were 1145, 845, 629 and 223 fmol/mg protein, respectively. When the binding in these fractions was compared with the activity of plasma membrane 'marker' enzymes in the same fractions a relative enrichment of [3H]prazosin binding sites was found in the residual microsomes and one of the Golgi fractions. Photoaffinity labelling with 125I-arylazidoprazosin in combination with SDS-polyacrylamide gel electrophoresis revealed the specific binding to 40 and 23 kDa entities in a Golgi fraction, while in plasma membranes the binders had an apparent molecular mass of 36 and 23 kDa. When [3H]prazosin was injected in vivo into rat portal blood followed by subcellular fractionation of liver, a pattern of an initial rapid decline and thereafter a slow decline of radioactivity was noted in all fractions. Additionally, in the two Golgi fractions a transient accumulation of radioactivity occurred between 5 and 10 min after the injection. The ED50 values for displacement of [3H]prazosin with adrenaline was lowest in the plasma membrane fraction, followed by the residual microsomes and Golgi fractions, the values were 10(-6), 10(-5) and 10(-4) mol/l, respectively. On the basis of lack of correlation between distribution of alpha 1-adrenergic antagonist binding and adenylate cyclase activity, differences in the molecular mass of alpha 1-adrenergic antagonist binders, differences in the kinetics of in vivo binding and accumulation of [3H]prazosin and also differences in agonist affinity between plasma membrane and Golgi fractions, it is concluded that alpha 1-adrenergic receptors are localized to low-density intracellular membranes involved in receptor biosynthesis and endocytosis.     

Rapid modulation of N-formyl chemotactic peptide receptors on the surface of human granulocytes: formation of high-affinity ligand- receptor complexes in transient association with cytoskeleton

When human granulocytes were exposed to 50 nM N-formyl-Met-Leu-[3H]Phe at 37 degrees C they rapidly formed ligand-receptor complexes that dissociated 50-100 times more slowly than those on cells initially exposed to the peptide at 4 degrees C. These complexes of apparent higher affinity were stable after detergent solubilization of the cells with Triton X-100. The complexes co-isolated with the detergent insoluble cytoskeletal residues and were free of the cytosolic and Golgi markers, lactate dehydrogenase and galactosyl transferase, respectively. After 5 s of exposure to f-Met-Leu-Phe, 2,000-3,000 molecules of ligand per cell were trapped in such complexes. Continued exposure resulted in capture of a maximum of 14,000 molecules per cell by 5 min. Exposure at 15 degrees C, a temperature at which endocytosis of the receptor is prevented, resulted in complex formation at a linear rate for at least 20 min to levels twice those measured at 37 degrees C. At 4 degrees C, complex formation was approximately 10% of the maximum amount formed at 37 degrees C. Pulse-chase experiments revealed that the complex was in transient association with the cytoskeleton with a half life ranging between 30 s to 4 min depending on the length of the original incubation. Electron microscopic autoradiography indicated that after 1 min of incubation at 37 degrees C, the majority of the specific autoradiographic grains were localized to the outer circumference of the cellular cytoskeleton. After 4 min of incubation, the grains were less frequent at the cytoskeleton periphery but still threefold enriched over a random cellular distribution. We conclude that a metabolically controlled modulation of the state of the N-formyl chemotactic peptide receptor occurs in the plasma membrane which may be the result of transient association of ligand-receptor complex and the cell cytoskeleton.     

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

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

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

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

Isolation of a vesicular intermediate in the cell-free transfer of membrane from transitional elements of the endoplasmic reticulum to Golgi apparatus cisternae of rat liver

Preparations enriched in part-smooth (lacking ribosomes), part-rough (with ribosomes) transitional elements of the endoplasmic reticulum when incubated with ATP plus a cytosol fraction responded by the formation of blebbing profiles and approximately 60-nm vesicles. The 60-nm vesicles formed resembled closely transition vesicles in situ considered to function in the transfer of membrane materials between the endoplasmic reticulum and the Golgi apparatus. The transition elements following incubation with ATP and cytosol were resolved by preparative free-flow electrophoresis into fractions of differing electronegativity. The main fraction contained the larger vesicles of the transitional membrane elements, while a less electronegative minor shoulder fraction was enriched in the 60-nm vesicles. If the vesicles concentrated by preparative free-flow electrophoresis were from material previously radiolabeled with [3H]leucine and then added to Golgi apparatus immobilized to nitrocellulose, radioactivity was transferred to the Golgi apparatus membranes. The transfer was rapid (T1/2 of about 5 min), efficient (10-30% of the total radioactivity of the transition vesicle preparations was transferred to Golgi apparatus), and independent of added ATP but facilitated by cytosol. Transfer was specific and apparently unidirectional in that Golgi apparatus membranes were ineffective as donor membranes and endoplasmic reticulum vesicles were ineffective as recipient membranes. Using a heterologous system with transition vesicles from rat liver and Golgi apparatus isolated from guinea pig liver, coalescence of the small endoplasmic reticulum-derived vesicles with Golgi apparatus membranes was demonstrated using immunocytochemistry. Employed were polyclonal antibodies directed against the isolated rat transition vesicle preparations. When localized by immunogold procedures at the electron microscope level, regions of rat-derived vesicles were found fused with cisternae of guinea pig Golgi apparatus immobilized to nitrocellulose strips. Membrane transfer was demonstrated from experiments where transition vesicle membrane proteins were radioiodinated by the Bolton-Hunter procedure. Additionally, radiolabeled peptide bands not present initially in endoplasmic reticulum appeared following coalescence of the derived vesicles with Golgi apparatus. These bands, indicative of processing, required that both Golgi apparatus and transition vesicles be present and did not occur in incubated endoplasmic reticulum preparations or on nitrocellulose strips to which no Golgi apparatus were added.(ABSTRACT TRUNCATED AT 400 WORDS)     

Intracellular transport of a newly synthesized asialoglycoprotein receptor in rat liver

Intracellular transport of a newly synthesized asialoglycoprotein receptor was studied biochemically using a monospecific antibody for the receptor. Pulse-labeling by intravenous injection of [3H]leucine and pulse-chasing after 10 min by cycloheximide injection resulted in the maximal labeling of the receptor in the rough microsomes at 15 min, in the smooth microsomes and the heavy Golgi subfraction (GF3) at 25 min and in the intermediate plus light Golgi subfraction (GF1+2) at 30 min. By 60 min, the labeling in GF1+2 had decreased and leveled off. In the plasma membrane fraction, the labeled receptor first appeared at 20 min, increased rapidly and also reached a constant level at 40-60 min. Intracellular movement of the newly synthesized receptor in the GF1+2 and plasma membrane fractions was also investigated by purifying the receptor protein from the GF1+2 and plasma membrane fractions by affinity chromatography. It was revealed that the specific radioactivities of the receptor in the two fractions become equilibrated after 60-120 min. The receptor of the various membrane fractions was also pulse-labeled in vivo for 20 min simultaneously with [3H]glucosamine and [14C]leucine, and pulse-chased for the following 40 min. After pulse-labeling for 20 min, the ratio of the radioactivity of [3H]glucosamine or [3H]sialic acid to [14C]leucine of the receptor from the rough and smooth microsomes, and GF3, GF2, and GF1 increased in that order. That of the receptor from the plasma membrane fraction was infinitely higher, because, while a significant amount of 3H-radioactivity was incorporated into the receptor in the Golgi apparatus, only a negligible amount of 14C-radioactivity was incorporated into the same receptor in the plasma membrane due to the delay in the arrival of [14C]leucine labeled receptor to the plasma membrane. After chasing for 40 min, however, the same radioactivity ratios of the GF1 and plasma membrane fractions approached each other. All these results strongly suggest that the distribution of the newly synthesized receptor becomes rapidly equilibrated between the trans-Golgi components and plasma membranes probably by repeated recycling of the receptor protein between the two membranes.     

Function of neutral endopeptidase on the cell membrane of human neutrophils

Intact human neutrophils hydrolyzed N-formyl-Met-Leu-[3H]Phe (fMLP) and released Leu-[3H]Phe, cleaving 45-50% of the peptide within 20 min at 37 degrees C. The dipeptide after its release was then hydrolyzed to free amino acids by a dipeptidase (EC 3.4.13.11). This activity, present in plasma membrane-enriched fractions of neutrophil lysates, was also inhibited over 90% by phosphoramidon, an inhibitor of neutral endopeptidase (NEP, EC 3.4.24.11). Dithiothreitol and EDTA inhibited the activity to a comparable degree, suggesting the requirement for a heavy metal cofactor. Bestatin and amastatin, inhibitors of aminopeptidases (but not human kidney NEP), did not inhibit the rate of fMLP degradation but prevented the production of free phenylalanine and enhanced the accumulation of Leu-Phe. Of other inhibitors, alpha 1-antitrypsin and alpha 2-macroglobulin slightly enhanced the rate of fMLP hydrolysis by neutrophils, and others tested were ineffective. Rabbit antiserum to homogeneous human kidney NEP reacted specifically with a 100-kDa protein present in sodium dodecyl sulfate-solubilized neutrophils. The Mr of this protein was slightly larger than that of the kidney enzyme in sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The antiserum incubated with intact cells specifically inhibited the degradation of fMLP over 70%. First, we confirm that NEP present on the plasma membrane cleaves fMLP at the Met-Leu bond; then the dipeptide Leu-Phe is cleaved by a dipeptidase. Finally, inhibition of NEP completely blocks fMLP-mediated chemotaxis. Thus, the enzyme may play an important role in modulating chemotactic responses.     

NADH-activated cell-free transfer between Golgi apparatus and plasma membranes of rat liver.

This report concerns development of a cell-free system from rat liver to study transport of membrane constituents from the Golgi apparatus to the plasma membrane. Highly purified Golgi apparatus as donor and a mixture of sheets and vesicles as plasma membrane acceptor fractions were combined to analyze requirements for lipid and protein transport. In the reconstituted system, the Golgi apparatus donor was in suspension. To measure transfer, membrane constituents of the donor membranes were radiolabeled with [3H]acetate (lipids) or [3H]leucine (proteins). The plasma membrane vesicles were used as the acceptor and were unlabeled and immobilized on nitrocellulose for ease of recovery and analysis. The reconstituted cell-free transfer was dependent on temperature, but even at 37 degrees C, the amount of transfer did not increase with added ATP, was not specific for any particular membrane fraction or subfraction nor was it facilitated by cytosol. ATP was without effect both in the presence or absence of a cytosolic fraction capable of the support of cell-free transfer in other systems. In contrast to results with ATP, NADH added to the reconstituted system resulted in an increased amount of transfer. A further increase in transfer was obtained with NADH plus a mixture of ascorbate and dehydroascorbate to generate ascorbate free radical. The transfer of labeled membrane constituents from the Golgi apparatus to the plasma membrane supported by NADH plus ascorbate radical was stimulated by a cytosol fraction enriched in less than 10 kDa components. This was without effect in the absence of NADH/ascorbate radical or with ATP as the energy source. Specific transfer was inhibited by both N-ethylmaleimide and GTP gamma S. The findings point to the possibility of redox activities associated with the trans region of the Golgi apparatus as potentially involved in the transport of membrane vesicles from the Golgi apparatus to the cytoplasmic surface of the plasma membrane.     

Secretion kinetics of hydroxyproline-containing macromolecules in carrot root discs

Short-term pulse-chase studies using radioactive L-proline on carrot tissue support the classical endomembrane route for secretory proteins. Labelled hydroxyproline residues were first detectable in fractions containing the endoplasmic reticulum (ER) after a 5 min pulse. Upon chase-out this fraction looses and, initially, the Golgi apparatus (GA) fraction gains radioactivity. Unlike ER and GA fractions which show chase-out characteristics a plasma membrane (PM) containing-fraction reveals retention of some of the radioactivity.     

Subcellular distribution of α1-adrenergic receptors in rat liver

The distribution of α₁-adrenergic receptors in rat liver subcellular fractions was studied using the α₁-adrenergic receptor ligand [³H]prazosin. The highest number of [³H]prazosin binding sites was found in a plasma membrane fraction followed by 2 Golgi and a residual microsomal fraction, the numbers of binding sites were 1145, 845, 629 and 223 fmol/mg protein, respectively. When the binding in these fractions was compared with the activity of plasma membrane ‘marker’ enzymes in the same fractions a relative enrichment of [³H]prazosin binding sites was found in the residual microsomes and one of the Golgi fractions. Photoaffinity labelling with ¹²⁵I-arylazidoprazosin in combination with SDS-polyacrylamide gel electrophoresis revealed the specific binding to 40 and 23 kDa entities in a Golgi fraction, while in plasma membranes the binders had an apparent molecular mass of 36 and 23 kDa. When [³H]prazosin was injected in vivo into rat portal blood followed by subcellular fractionation of liver, a pattern of an initial rapid decline and thereafter a slow decline of radioactivity was noted in all fractions. Additionally, in the two Golgi fractions a transient accumulation of radioactivity occurred between 5 and 10 min after the injection. The ED₅₀ values for displacement of [³H]prazosin with adrenaline was lowest in the plasma membrane fraction, followed by the residual microsomes and Golgi fractions, the values were 10⁻⁶, 10⁻⁵ and 10⁻⁴ mol/l, respectively. On the basis of lack of correlation between distribution of α₁-adrenergic antagonist binding and adenylate cyclase activity, differences in the molecular mass of α₁-adrenergic antagonist binders, differences in the kinetics of in vivo binding and accumulation of [³H]prazosin and also differences in agonist affinity between plasma membrane and Golgi fractions, it is concluded that α₁-adrenergic receptors are localized to low-density intracellular membranes involved in receptor biosynthesis and endocytosis.     

Differences in distribution of ribonuclease isoenzymes in cytosol and granules in normal human granulocytes and in granulocytes of patients with chronic granulocytic leukemia (CGL)

Distribution of ribonuclease (RNAase), acid phosphatase (acid Ph-ase) and beta glucuronidase (BGU) between the granule, cytosol-soluble and post-granule fractions in normal human granulocytes and in granulocytes of chronic granulocytic leukemia (CGL) was studied. CGL granulocytes were found to display relative RNAase activity 1.2 times higher, relative acid Ph-ase activity 2.5 times higher than normal granulocytes. The granule fraction of CGL granulocytes showed 1.4 times higher relative RNAase activity but 0.87 times lower acid Ph-ase activity and the same BGU activity as normal granulocytes. On the other hand, the supernatant soluble fraction of CGL granulocytes showed 4.4 times higher relative RNAase activity, 1.2 times higher relative acid Ph-ase activity and BGU 2.2 times higher than in cytosol soluble fraction of normal granulocytes. Thus, cytosol soluble fraction of CGL granulocytes show a relative activity of the lysosomal enzymes studied which is remarkably higher than in normal granulocytes. The percentage distribution of RNAase, acid Ph-ase and BGU showed that CGL granulocytes contain only 36% of total RNAase activity versus 46% of that in normal ones. On the other hand, CGL granulocytes in cytosol soluble fraction will contain 48% of total RNAase versus 29% of total RNAase in cytosol of normal granulocytes. The isoenzyme profiles of RNAase of granule fractions were similar in normal and CGL granulocytes, while the RNAase isoenzyme profiles of cytosol fractions were different for normal and CGL granulocytes, indicating that some essential part of CGL granulocyte cytosol RNAase differs from RNAase contained in granules and in cytosol of normal granulocytes.     

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.     

Isolation and partial characterization of outer and inner membranes from encapsulated Haemophilus influenzae type b.

A method has been developed to separate the cell envelope of encapsulated (type b) Haemophilus influenzae into its outer and inner membrane components with procedures that avoided two problems encountered in fractionation of this envelope: (i) the tendency of the outer and inner membranes to hybridize and (ii) the tendency of the apparently fragile inner membrane to fragment into difficulty sedimentable units. Log phage cells, whose lipids were radioactively labeled, were lysed by passage through a French press. The lysate was applied to a discontinuous sucrose gradient, and envelope-rich material was collected by centrifugation onto a cushion of dense sucrose under carefully controlled conditions. This material was then further fractionated by isopycnic centrifugation in a sucrose gradient to yield four membrane fractions which were partially characterized. On the basis of their radioactivity, buoyant density, ultrastructure, polypeptide composition, and content of phospholipid, protein, lipopolysaccharide, and succinic dehydrogenase, these fractions were identified as follows: fraction 1, outer membrane vesicles with very little inner membrane contamination (less than 4%); fraction 2, outer membrane vesicles containing entrapped inner membrane; fraction 3, a protein-rich fraction of inner membrane; fraction 4, a protein-poor fraction of inner membrane. Fractions 3 and 4 contained about 25% outer membrane contamination.     

Fate of injected glucagon taken up by rat liver in vivo. Degradation of internalized ligand in the endosomal compartment.

The uptake and processing of glucagon into liver endosomes were studied in vivo by subcellular fractionation. After injection of [[125I]iodo-Tyr10]glucagon and [[125I]iodo-Tyr13]glucagon to rats, the uptake of radioactivity into the liver was maximum at 2 min (6% of the dose/g of tissue). On differential centrifugation, the radioactivity in the homogenate was recovered mainly in the nuclear (N), microsomal (P) and supernatant (S) fractions, with maxima at 5, 10 and 40 min, respectively; recovery of radioactivity in the mitochondrial-lysosomal (ML) fraction did not exceed 6% and was maximal at 20 min. On density-gradient centrifugation, the radioactivity associated first (2-10 min) with plasma membranes and then (10-40 min) with Golgi-endosomal (GE) fractions, with 2-5-fold and 20-150-fold enrichments respectively. Subfractionation of the GE fractions showed that, unlike the Golgi marker galactosyltransferase, the radioactivity was density-shifted by diaminobenzidine cytochemistry. Subfractionation of the ML fraction isolated at 40 min showed that more than half of the radioactivity was recovered at lower densities than the lysosomal marker acid phosphatase. Throughout the time of study, the [125I]iodoglucagon associated with the P, PM and GE fractions remained at least 80-90% trichloroacetic acid (TCA)-precipitable, whereas that associated with other fractions, especially the S fraction, became progressively TCA-soluble. On gel filtration and h.p.l.c., the small amount of degraded [125I]iodoglucagon associated with GE fractions was found to consist of monoiodotyrosine. Chloroquine treatment of [125I]iodoglucagon-injected rats caused a moderate but significant increase in the late recovery of radioactivity in the ML, P and GE fractions, but had little effect on the association of the ML radioactivity with acid-phosphatase-containing structures. Chloroquine treatment also led to a paradoxical decrease in the TCA-precipitability of the radioactivity associated with the P and GE fractions. Upon h.p.l.c. analysis of GE extracts of chloroquine-treated rats, at least four degradation products less hydrophobic than intact [125I]iodoglucagon were identified. Radio-sequence analysis of four of these products revealed three cleavages, affecting bonds Ser2-Gln3, Thr5-Phe6 and Phe6-Thr7. When GE fractions containing internalized [125I]iodoglucagon were incubated in iso-osmotic KCl at 30 degrees C, a rapid generation of TCA-soluble products was observed, with a maximum at pH 4. We conclude that endosomes are a major site at which internalized glucagon is degraded, endosomal acidification being required for optimum degradation.     

Biosynthesis of high density lipoprotein by chicken liver: conjugation of nascent lipids with apoprotein A1

To study the assembly of newly synthesized lipids with apoprotein A1, we administered [2-3H]glycerol to young chickens and determined the hepatic intracellular sites of lipid synthesis and association of nascent lipids with apoprotein A1. [2-3H]glycerol was rapidly incorporated into hepatic lipids, reaching maximal levels at 5 min, and this preceded the appearance of lipid radioactivity in the plasma. The liver was fractionated into rough and smooth endoplasmic reticulum and Golgi cell fractions. The isolated cell fractions were further subfractionated into membrane and soluble (content) fractions by treatment with 0.1 M Na2CO3, pH 11.3. At various times, the lipid radioactivity was measured in each of the intracellular organelles, in immunoprecipitable apoprotein A1, and in materials that floated at buoyant densities similar to those of plasma lipoproteins. Maximal incorporation occurred at 1 min in the rough endoplasmic reticulum, at 3-5 min in the smooth endoplasmic reticulum, and at 5 min in the Golgi cell fractions. The majority (66-93%) of radioactive glycerol was incorporated into triglycerides with smaller (4-27%) amounts into phospholipids. About 80% of the lipid radioactivity in the endoplasmic reticulum and 70% of that in the Golgi cell fractions was in the membranes. The radioactive lipids in the content subfraction were distributed in various density classes with most nascent lipids floating at a density less than or equal to 1.063 g/ml. Apoprotein A1 from the Golgi apparatus, obtained by immunoprecipitation, contained sixfold more nascent lipids than did that from the endoplasmic reticulum. These data indicate that [2-3H]glycerol is quickly incorporated into lipids of the endoplasmic reticulum and the Golgi cell fractions, that most of the nascent lipids are conjugated with apoproteins A1 in the Golgi apparatus, and that very little association of nascent lipid to apoprotein A1 occurs in the endoplasmic reticulum.     

Cerebral metabolism of plasma [14C]palmitate in awake,adult rat: Subcellular localization

Following intravenous injection of [U-¹⁴C]palmitate in awake adult rats, whole brain radioactivity reached a broad maximum between 15–60 min, then declined rapidly to reach a relatively stable level between 4 hr and 20 hr. At 44 hr total radioactivity was 57% of the 4 hr value (p<0.05). About 50% of palmitate which entered the brain from the blood was oxidized rapidly, producing¹⁴C-labeled water-soluble components which later left the cytosol. Radioactivity in the cytosolic fraction peaked at 45 min and then declined, coincident with the decline in total brain radioactivity. Membrane fractions were rapidly labeled to levels which remained relatively stable from 1 to 44 hr. Increases in the relative distributions of radioactivity were seen between 1 and 4 hr for the microsomal and mitochondrial fractions, and beyond 4 hr for the synaptic and myelin membrane fractions (p<0.05). Radioactivity in membrane fractions was 80–90% lipid, 5–13% water-soluble components and 3–17% protein. The proportion of label in membrane-associated protein increased with time. Proportions of radioactivity in the combined membrane fractions increased from 65% to 76% to 80% at 4, 20 and 44 hr, respectively. The results show that plasma-derived palmitate enters oxidative and synthetic pathways to an equal extent, immediately after entry into the brain. At and after 4 hr, the radiolabel resides predominantly in stable membrane lipids and protein. Brain radioactivity at 4 hr can be used therefore, to examine incorporation of palmitate into lipids in vivo, in different experimental conditions.     

Plasma-membrane location of phosphatidylinositol hydrolysis in rabbit neutrophils stimulated with formylmethionyl-leucylphenylalanine.

Rabbit peritoneal neutrophils, disrupted by sonication, were separated into three subcellular fractions by sucrose-step-gradient centrifugation and these were analysed with respect to biochemical markers. They comprised a high-speed supernatant containing the cytosol, a light particulate fraction enriched in Golgi and plasma membranes and a heavy particulate fraction enriched in granules and nuclei. The light particulate fraction was further separated into its components, which were identified as Golgi membranes (galactosyltransferase activity) and plasma membranes ((radioactivity derived from labelling intact cells with [125I]di-iodosulphanilic acid diazonium salt and [3H]formylmethionyl-leucylphenylalanine ([3H]fMet-Leu-Phe) binding)). In cells prelabelled with [3H]glycerol, the hydrolysis of phosphatidylinositol due to cell stimulation with fMet-Leu-Phe (10 nM) was shown to occur in the light particulate fraction. The [32P]Pi-labelling of phosphatidate, which is an early consequence of phosphatidylinositol hydrolysis, also occurred in this fraction. Analytical sucrose-gradient centrifugation of the light particulate fraction showed that the stimulated increment in [32P]phosphatidate (and thus by implication the initial phosphatidylinositol breakdown) was localized in the plasma membrane.