Studies on the metabolism of rat serum very low density apolipoprotein.

There was a rapid transfer of radioactive peptides to other lipoprotein fractions during the first 30 min after the intravenous injection of 125I-labeled rat very low density lipoprotein (VLDL) into rats. After this initial redistribution of radioactivity, label disappeared slowly from all lipoprotein fractions. The disappearance of 125I-labeled human VLDL injected into rats was the same as that of rat VLDL. Most of the radioactivity transferred from VLDL to low density (LDL) and high density (HDL) lipoproteins was associated with two peptides, identified in these studies by polyacrylamide gel electrophoresis as zone IVa and IVb peptides (fast-migrating peptides, possibly analogous to some human C apolipoproteins), although radioactivity initially associated with zone I (analogous to human apolipoprotein B) and zone III (not characterized) was also transferred to LDL and HDL. That the transfer of label from VLDL to LDL and HDL primarily involved small molecular weight peptides was confirmed in studies using VLDL predominantly labeled in these peptides by in vitro transfer from 125I-labeled HDL. Both zone I and zone IV radioactivity was rapidly removed from VLDL during the first 5 min after injection. However, although most of the zone IV radioactivity was recovered in LDL and HDL, only 12% of the label lost from zone I of VLDL was recovered in other lipoproteins, with the remainder presumably having been cleared from the plasma compartment. We have concluded that, during catabolism of rat VLDL apoprotein, there is a rapid transfer of small molecular weight peptides to both LDL and HDL. During the catabolic process, most of the VLDL is rapidly removed from the circulation, with only a small portion being transformed into LDL molecules.     

Lipoproteins in a nonrecirculating perfusate of rat liver

Rat livers were perfused in a nonrecirculating system for 30-40 min with Krebs-Ringer bicarbonate-0.1% glucose solution gassed with 95% O(2)-5% CO(2) at 37 degrees C at a flow rate of 3 ml/g/min. The livers appeared normal as judged by O(2) uptake, bile flow, transaminase release, and net protein output (2.5 mg/g/hr). The perfusate was concentrated by ultrafiltration using Amicon PM-10 or PM-30 membranes. The concentrated perfusate was subjected to sequential ultracentrifugation at solution densities of 1.006, 1.04, 1.06, and 1.21, and the top fractions were analyzed for protein and lipid. The net release of protein in the four density classes, suitably corrected, averaged 39, 10, 5, and 20 micro g/g/hr. The lipid composition of the perfusate lipoprotein fractions differed from that of serum mainly in the high percentage of free cholesterol, reflecting the lack of exposure to lecithin:cholesterol acyltransferase. When rat serum was fractionated in the same way, most of the lipoprotein in the d 1.006-1.06 range had a density greater than 1.04. It was concluded from these experiments that the liver secretes very low density lipoprotein (VLDL), high density lipoprotein (HDL), and a modified form of VLDL containing less lipid. Comparison of secretion rates and serum lipoprotein levels leads to the conclusion that the latter are largely determined by catabolic rates. When labeled amino acids were present, the perfusate HDL had a higher specific activity than VLDL. Addition of carrier whole serum did not alter recovery of labeled lipoproteins, but when these were isolated from Golgi membranes after a 40-min perfusion, more than twice as much label was recovered in HDL, suggesting the presence of precursors within the Golgi. The main advantages of the nonrecirculation perfusion technique are the avoidance of catabolic reactions, simplicity, and complete control over the composition of the perfusing medium.     

Secretion of apolipoproteins in very low density and high density lipoproteins by perfused rat liver

The incorporation of labeled amino acids into the peptides of very low density lipoproteins (VLDL) and high density lipoproteins (HDL) secreted by perfused rat liver was studied using a Ringer-albumin solution in the perfusate in place of serum to diminish exchange of peptides between VLDL and HDL. Among the lipoproteins, the greatest release of protein, greatest incorporation of amino acid, and highest specific activity were found in VLDL. After separation of the delipidated peptides by electrophoresis on polyacrylamide gel, the incorporation into VLDL peptides was found to be 5-10 times as great as into HDL peptides. There was virtually no incorporation into the peptides of low density lipoproteins (LDL). Approximately 25% of the radioactivity incorporated into perfusate VLDL failed to enter the 13% polyacrylamide gel. The remaining radioactivity was distributed primarily among three peptide bands; one, found in the upper portion of the gel, contained 45% of the total, most of the remainder being found in two rapidly migrating bands. These three peptides appear to approximate those of human apo-C in relative electrophoretic mobility. Most of the HDL peptide radioactivity entering the running gel was found in a band that migrates slightly faster than the main VLDL band. A portion of the radioactivity of this major HDL band did not enter the running gel unless beta-mercaptoethanol was present. Greater separation of these two bands by polyacrylamide gel electrophoresis for 24 hr confirmed that the major bands in VLDL and in HDL were different. The rapidly moving peptides of HDL were found to contain very little radioactivity. Determination of the intensity of staining of carrier-free perfusate VLDL and HDL peptides produced a pattern similar to the incorporation of labeled amino acids. It is concluded that the rapidly moving peptides, which may contain activators of lipoprotein lipase, are only secreted as part of the VLDL.     

The intracellular distribution of labelled lipoproteins in the tissues of rats under physical loading]

A study was made of the influence of a 3 hour physical loading on the intracellular distribution of 125I-labeled very low density lipoprotein (VLDL), low density lipoprotein (LDL), high density lipoprotein (HDL) in the rat tissues after intravenous injection. The uptake of VLDL by liver was decreased, that of LDL was not altered and that uptake of HDL was increased, Redistribution of labeled lipoproteins between the subcellular structures was found. Accumulation of labeled VLDL in cytosol, microsome and large membranes was observed in muscles. The radioactivity level of VLDL was decreased in lysosomes, whereas the level of HDL was increased, Physical loading increased the uptake of HDL in adrenal glands. Accumulation of radioactivity was found in cytosol and small membranes. The data confirm the important role of lipoproteins of cellular metabolism regulation.     

Characterization of nascent lipoproteins produced by perfused rat liver: evidence of hepatic secretion and post-secretory modification of nascent lipoproteins

We characterized the lipoproteins produced by perfused rat liver in recirculating and non-recirculating systems. The apolipoprotein (apo) B of the perfusate very low density lipoprotein (VLDL) and low density lipoprotein (LDL) were labeled with a radioactive precursor amino acid in both systems, suggesting that newly synthesized apo B was secreted in association with VLDL and LDL. When the lipoproteins obtained from the non-recirculating perfusate were injected into rats in vivo, the half life of the VLDL was 13 min and most of it was converted to LDL, while that of the LDL was 5.2 h, indicating that the perfusate LDL was different from the VLDL with respect to its metabolic fate. These observations suggest that both VLDL and LDL are produced as independent primary products in the liver, although the majority of LDL is derived from VLDL in vivo. The nascent lipoproteins in the non-recirculating perfusate were richer in apo E than those in the recirculating perfusate, and a part of the apo E disappeared when the VLDL was added to the recirculating perfusate. The particle sizes of the VLDL and LDL were examined by electron microscopy, which revealed that those in the non-recirculating perfusate were more homogeneous and smaller than the plasma counterparts, while those in the recirculating perfusate were more heterogeneous and their mean diameter was closer to that of the plasma lipoproteins, than in the case of non-recirculating perfusate. These observations suggest that apo E secreted with the nascent lipoproteins may be picked up by the liver just after secretion, causing the heterogeneity in size, as observed in the case of plasma lipoproteins.     

Retention of apolipoprotein B and cholesterol by perfused heart during lipolysis of very-low-density lipoprotein

The fate and mechanism of removal of apolipoproteins and lipids of human very-low-density lipoproteins were determined in the perfused rat heart. Approx. 50% of the VLDL triacylglycerol was hydrolyzed during a 2 h perfusion. Phospholipid phosphorus, apolipoproteins C-II, C-III and E were quantitatively recovered in the medium. However, there was a loss of unesterified (17 +/- 6%) and esterified (19 +/- 8%) cholesterol from the perfusion medium. Apolipoprotein B was retained by the heart, as determined by the loss of immunoassayable apolipoprotein B (30 +/- 5%) or the uptake of 125I-labelled apolipoprotein of VLDL (9 +/- 2%) from the perfusion medium. The discrepancy in the two methods for estimating apolipoprotein removal was shown to be due to the modification of apolipoprotein B-containing lipoproteins, which was such that they were no longer precipitated with antibodies to apolipoprotein B. The labelled apolipoprotein B, retained by the heart, could be partially released by perfusion of the heart with buffer containing heparin (14 +/- 2%) or trypsin (50 +/- 2%). Labelled apolipoprotein uptake by the heart was reduced by 90% when lipoprotein lipase was first released by heparin or when VLDL was treated with 1,2-cyclohexanedione to modify arginine residues of apolipoproteins. Very little extensive degradation of the apoprotein to low molecular weight material occurred during the 2 h perfusion, since 95% of the tissue label was precipitated by trichloroacetic acid. It is concluded that there is retention of apolipoprotein B, cholesteryl ester and cholesterol by the perfused heart during catabolism of VLDL. The data are consistent with the concept that the retention of apolipoprotein B requires membrane-bound lipoprotein lipase or an interaction with the cell surfaces that is modified by heparin. The overall process also involves arginine residues of apolipoproteins. At least 50% of the labelled apolipoprotein retained in the tissue is associated with lipoprotein lipase and other cell surface sites, while the remainder may be taken up by the cells.     

Synthesis and release of low density lipoproteins by the isolated perfused pig liver.

In previous studies, we have shown that a relatively large amount of low density lipoproteins is released into the perfusate during isolated pig liver perfusion. The present studies were done to determine the source of these lipoproteins. Breakdown of the very low density lipoproteins to low density lipoproteins by the perfusion apparatus or by hepatic catabolism was excluded by adding 125I very low density lipoproteins to the perfusate in the presence and absence of a liver and then measuring the radioactivity in the low density lipoprotein fraction after rate-zonal ultracentrifugation. Release of preformed low density, lipoproteins from the liver was investigated by injecting iodine-labeled low density lipoproteins in vivo several hours prior to perfusion of the liver and then measuring the release of labeled low density lipoproteins into the perfusate. It was shown that intact labeled low density lipoproteins were released by the perfused liver. De novo synthesis of the low density lipoproteins was established by measuring the incorporation of [1-14C]leucine into this lipoprotein fraction. The radioactivity in the low density lipoprotein fraction increased with time and accounted for 20 to 25% of the total radioactivity incorporated into all the lipoprotein fractions. The incorporation of [1-14C]leucine into the low density lipoproteins was confirmed by rate-zonal analysis. We conclude that the low density lipoproteins in the perfusate from pig liver perfusions were derived mainly from a preformed liver pool, but also partly from de novo synthesis by the liver.     

Surface binding and interiorization of homologous and heterologous serum lipoproteins by rat aortic smooth muscle cells in culture.

Rat aortic smooth muscle cells in culture were incubated with rat or human iodinated low and high density lipoprotein at 5-50 mug/ml for 3 h. With the homologous lipoproteins, 25-49% of total cellular protein radioactivity was trypsin releasable and was considered as surface-bound radioactivity, while the balance represented cellular uptake. The ratio of surface-bound to cellular label was higher when the cells were incubated with human lipoproteins and was about 9 : 1 with human high density lipoprotein. Cellular uptake of rat low density lipoprotein was about twice that of rat high density lipoprotein, while degradation of labeled protein, which had presumably followed protein uptake, was similar and ranged from 20 to 25% of protein uptake in 3 h. Experiments designed to test the effect of cell density on lipoprotein uptake have shown that the uptake was related inversely to cell density. Thus, the lower lipoprotein uptake encountered in the rat smooth muscle cells, compared to that described for human fibroblasts (Goldstein, J.L. and Brown, M.S. (1974) J. Biol. Chem. 249, 5153-5162), could be due in part to the much lower cell density used in the latter studies, as well as to cell type and species difference.     

N-oxidation of imipramine by isolated perfused rat and rabbit lung

Pulmonary uptake and metabolism of imipramine (IMP) was investigated in isolated perfused rat (IPrL) and rabbit (IPRL) lung preparations. Perfusate containing ¹⁴C-IMP (1.2 μmole/g lung) was recirculated through the pulmonary artery in artificially ventilated lungs. The radioactivity in the perfusate declined rapidly and about 80% of the dose was taken up by the lungs within 10 minutes in both IPrL and IPRL preparations. A steady-state was apparently reached thereafter in the IPRL, while a portion of the radiolabel effluxed into the perfusate of the IPrLs, thus reducing the net lung content to 54% of added IMP by 60 minutes. After 60 minutes perfusion, metabolites of IMP accounted for the major radioactivity (80%) in the perfusate, while the lung contained mainly (83%) the unchanged parent compound. The principal metabolite was identified as IMP-N-oxide (IMP-NO) which was found in the perfusate after 5 minutes of perfusion. Only 3% of the added IMP was metabolized by IPRL in 60 minutes. SKF-525A, an inhibitor of cytochrome P-450-mediated monooxygenase system, did not inhibit but enhanced the metabolism of IMP by IPrL to IMP-NO. IMP was principally metabolized to IMP-NO by incubations of 9,000 g supernatant fractions of rat lungs to a significantly higher extent than similar rabbit lung preparations. Including SKF-525A significantly accelerated the metabolism of IMP to IMP-NO in accordance with the perfusion experiments. These results suggest that in contradiction to publishedd reports, IMP is appreciably metabolized by the rat lung $\text{via}$ N-oxidation by non-cytochrome P-450 pathway and the metabolite formed in the lung is released into the circulation indicating its low affinity for the lung tissue.     

The catabolism of human and rat very low density lipoproteins by perfused rat hearts.

The catabolism of human and rat 125I-labelled very low density lipoproteins (VLDL) was compared by perfusing the lipoproteins through beating rat hearts. Triacylglycerol was removed from the VLDL to a greater extent than the protein moiety, leaving remnants containing relatively more apo-B and less apo-C. The change in apo-C content of the remnants correlated with the loss of triacylglycerol. The extent of removal of triacylglycerol from the rat and human VLDL was similar and in most cases appeared to saturate the heart lipoprotein lipase. The remnants were slightly smaller in size than the VLDL, and included particles which appeared to be partially emptied. In addition to remnants of d less than 1.019 g/ml, iodinated lipoproteins derived from rat and human VLDL were recovered at d 1.019-1.063 and 1.063-1.21 g/ml. The former contained largely cholesterol and cholesteryl esters, while phospholipids were the dominant lipid in the latter. An average of 40% of the 125I-labelled apoprotein lost from the VLDL was associated with the perfused hearts. Very little d 1.019-1.063 g/ml lipoprotein was produced from low (physiological) concentrations of rat VLDL, most of the lipoprotein being removed by the heart. However, lipoproteins of density 1.019-1.063 g/ml were formed from human VLDL at all concentrations in the perfusate, as well as from higher concentrations of the rat VLDL. Agarose gel filtration of lipoproteins following heart perfusion with human VLDL revealed large aggregates containing particles which resemble low density lipoproteins (LDL) in electron microscopic appearance and apoprotein composition, since they contain largely apo-B. These data suggest that at normal concentrations rat VLDL are almost completely catabolised and taken up by the heart without the formation of LDL, while LDL is produced from human VLDL at all concentrations.     

Proteolysis of very low density lipoprotein in perfused lung.

Perfusion of homologous 125I-labeled rat very low density lipoprotein through isolated rat lungs in the presence of heparin resulted in apoprotein proteolysis. At least the apoprotein C was degraded into two peptides smaller than 7500 daltons as measured by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The lung uptake of radioactivity was small and due mainly to the presence of the larger of the two peptides. The lung protease was not active against an 125-I-labeled albumin substrate and was not released into the medium by heparin.     

Very low density lipoprotein stimulation of triglyceride accumulation in rat preadipocyte cultures.

Exposure of cultured rat epididymal preadipocytes to human very low density lipoproteins (VLDL) resulted in the rapid accumulation of large amounts of cellular triglyceride which was accompanied by the appearance of numerous large cellular lipid inclusions. Addition of heparin produced a two-fold stimulation of lipoprotein induced triglyceride accumulation. Supplementation of the growth medium with either low density lipoprotein, oleic acid or artificial triglyceride emulsion did not produce cellular triglyceride levels equivalent to that obtained with VLDL. Fibroblastic cells from rat skin and lung did not accumulate triglycerides when exposed to VLDL and heparin.     

Uptake of lipoproteins by in situ perfused rat ovaries: identification of binding sites for high density lipoproteins

We have examined the uptake and distribution of 125I-labeled human high density lipoprotein, apolipoprotein E-free (hHDL3), 125I-rat high density lipoprotein (HDL), and human HDL (hHDL) reconstituted with [3H]cholesteryl linoleate after their in situ vascular perfusion to ovaries of gonadotropin-primed immature rats on days 6-9 post human chorionic gonadotropin (hCG)-injection. Some rats were treated with 4-aminopyrazolopyrimidine to reduce plasma lipoproteins and ovarian cholesteryl ester stores. Perfused ovaries were analyzed biochemically and autoradiographically, and progestin content of the ovarian effluent was quantified. Infusion of ovine luteinizing hormone and hHDL increased ovarian progestin secretion severalfold, indicating that the perfused ovary was functional. After perfusion with HDL reconstituted with [3H]cholesteryl linoleate, radioactive progestin appeared in the effluent; thus, sterol carried by exogenous HDL was converted to steroid. At 37 degrees C, uptake of 125I-hHDL3 was greatest after 15 min of perfusion with label. This was decreased by 80% when the perfusion was carried out at 4 degrees C and by 70-95% when excess unlabeled hHDL, but not human low density lipoprotein (hLDL), was included in the perfusate with 125I-hHDL. Aminopyrazolopyrimidine treatment enhanced 125I-hHDL uptake twofold. After perfusion for 15 min with 125I-hHDL3, radioactivity in the ovary was high for 3-30 min of HDL-free wash, then declined 75% by 30-60 min. With light and electron microscope autoradiography, 125I-hHDL3 was localized to corpora lutea, both along luteal cell surfaces and over their cytoplasm. The plasma membrane grains appeared to be associated with segments that lacked bristle coats. Perfusion with 125I-rat HDL produced a similar pattern of labeling. In ovaries perfused with 125I-BSA, silver grains were concentrated over macrophage-like cells but were sparse over luteal cells. We conclude that the in situ perfused rat ovary takes up 125I-hHDL3 by a temperature-dependent, lipoprotein-specific process, and that this lipoprotein is accumulated by luteal cells.     

Sites of uptake of3H-5-hydroxytryptamine in rat isolated lung

Summary The localisation of radioactivity in rat lungs after perfusion of³H-5-hydroxytryptamine (5-HT) was studied by autoradiography. Rat isolated lungs, perfused with Krebs bicarbonate solution, via the pulmonary circulation, were rapidly frozen after the infusion of³H-5-HT. All subsequent handling was carried out at −30 to −40°C. Developed sections were examined by the light microscope and showed that radioactivity was concentrated around the alveoli with little or no label in other parts of the lung. Lungs perfused with³H-5-HT in the presence of mebanazine, a monoamine oxidase inhibitor, showed label in the endothelial cells of arteries and arterioles as well as the alveolar label. Lungs treated with amitriptyline were essentially devoid of label. These results indicate that the site of the avid uptake and metabolism of 5-HT in the lung is the endothelial cells of the vasculature.     

Transfer of esterified cholesterol from serum lipoproteins to the liver.

The fate of cholesteryl esters of the serum lipoproteins was studied in intact rats and in isolated perfused rat livers. The lipoproteins of fasting rat serum were labeled in vitro with [3H]cholesteryl oleate. Following intravenous injection, it was found that the majority of the radioactive ester was rapidly taken up by the liver where hydrolysis of the ester bond occurred. At 5 min, 58% of the injected material was recovered in the liver, 85% of which was still in the ester form, while at 30 min only 22% of the liver radioactivity was in cholesteryl esters. There was very little difference in the rate at which radioactivity was taken up from the different lipoprotein classes. Similar phenomena were observed in the perfused liver, but it was found that although the radioactive esters were being taken up, there was no change in the concentrations of free or esterified cholesterol in the perfusing medium, indicating that the lipoprotein cholesteryl ester was gaining access to the liver through an exchange of molecules. After uptake, cell fractionation experiments showed that the plasma membranes had the greatest relative amounts of radioactivity, suggesting that this is the site of exchange. Small amounts of radioactivity were recovered in the bile, demonstrating that serum lipoproteins can serve as precursors of at least some of the bile steroids.     

Lipoprotein secretion in lean and obese Zucker female rats in vivo and in a single-pass-perfused liver preparation

The plasma lipoprotein composition as well as lipoprotein synthesis and secretion were studied in vivo and in a single-pass-perfused liver preparation in lean and obese Zucker rats. Compared with their lean littermates the levels in the plasma of very low density lipoprotein (VLDL), intermediate density lipoprotein (IDL) + low density lipoprotein (LDL) and high density lipoprotein (HDL) were increased 4-, 2- and 2.5 fold, respectively, in obese rats. In these rats both VLDL and IDL + LDL were enriched in triglycerides, while the HDL were enriched in cholesterol. Although the VLDL and IDL + LDL protein concentrations were the same in lean and obese rats, the HDL protein concentration was 3-fold greater in the obese rats. Both the lean and obese rats incorporated similar amounts of [14C]leucine into total liver protein. However, obese rats incorporated 2.5-fold and 6-fold more [14C]leucine into VLDL and HDL in vivo, 2.7-fold and 1.7 fold more [35S]methionine in VLDL and HDL present in the perfusate, than did lean rats. The perfusate [35S]S-labelled apoproteins (apo-B100, B48; apo-E, apo-AI, apo-AIV and apo-C) were separated by gel electrophoresis and identified by autoradiography. Incorporation of [3H]glycerol into liver, VLDL, IDL + LDL and HDL triglycerides was 2-, 48-, 13- and 1.5-fold higher in obese than in lean rats, respectively. The [3H]-labelled triglycerides in VLDL and IDL + LDL present in the perfusate was 5.4-fold and 4.4-fold more in obese rat. There was no difference in the incorporation of [3H]glycerol into triglycerides of perfusate HDL between the two genotypes of rats. Thus, the hypertriglyceridaemia observed in obese Zucker rats results from very high synthetic rates of both the lipid and protein moieties of plasma lipoproteins. Before this study, no report of the simultaneous triglycerides and protein synthesis in vivo and in a single-pass-perfused liver preparations had been reported.     

Effect of infusion of "tris-galactosyl-cholesterol" on plasma cholesterol, clearance of lipoprotein cholesteryl esters, and biliary secretion in the rat

As shown by us previously (van Berkel et al. 1985. J. Biol. Chem. 260: 2694-2699 and van Berkel et al. 1985. J. Biol. Chem. 260: 12203-12207) the clearance of both low density lipoproteins (LDL) and high density lipoproteins (HDL) from the blood can be greatly enhanced by pretreatment of these lipoproteins with a tris-galactosylated cholesterol derivative, which makes these particles recognizable by hepatic galactosyl-receptors. Here we report that intravenous infusion of the (water-soluble) tris-galactosyl-cholesterol in rats caused a dose-dependent decrease of the plasma cholesterol level. This fall was sustained long after termination of the infusion. It was not observed upon infusion of tris-glucosyl-cholesterol. The fall in plasma cholesterol was accompanied by an increase in hepatic cholesterol. Upon injection of rat HDL and LDL labeled in their cholesteryl ester moieties, plasma clearance of label in both lipoproteins was enhanced in rats infused with tris-galactosyl-cholesterol, the stimulation being more pronounced when the label was in HDL. The appearance of label in bile was also enhanced in the rats receiving the compound, again more markedly when the label was given as HDL. Ninety four percent or more of the radioactivity excreted in the bile was in the form of bile salts, with conjugated cholate being the major species in both control and treated rats; 6% or less of the radioactivity in the bile was as free cholesterol. Infusion of tris-galactosyl-cholesterol constitutes a new and defined method of lowering plasma lipoprotein levels by enhancing their uptake in the liver.     

Metabolism of 14C-arachidonate in rat isolated lung

Metabolism of ¹⁴C-arachidonate was investigated in rat isolated lungs perfused via the pulmonary circulation with Krebs solution. Only 10% of the radioactivity derived from an infusion of ¹⁴C-arachidonate through the pulmonary circulation of rat isolated lungs appeared in the effluent by 10 minutes. At 10 min, the major component of effluent radioactivity and 20–40% of that retained in lung was unchanged arachidonate. Between 10 and 20 min of perfusion, a further small amount of radioactivity was lost in lung effluent and at 20 min the retained radioactivity showed a decrease in the proportion present as free arachidonate. Between 20 and 60 min, there was no further loss of radioactivity in effluent and no further change in the distribution in lung. Addition of albumin to the Krebs solution perfusate during the infusion of ¹⁴C-arachidonate increased effluent radioactivity to 80%, but albumin added after 10 min only caused the efflux of a small amount of radioactivity (10%). Treatment of labelled lung at 20 min with the calcium ionophore A23187 released biologically active metabolites of arachidonate but very little radioactivity. Metabolism of arachidonate, either during the infusion or after retention in lung, in rat lung was closer to that in human lung than to that in guinea-pig lung.     

Metabolism of C-arachidonate in rat isolated lung

Metabolism of ¹⁴C-arachidonate was investigated in rat isolated lungs perfused via the pulmonary circulation with Krebs solution. Only 10% of the radioactivity derived from an infusion of ¹⁴C-arachidonate through the pulmonary circulation of rat isolated lungs appeared in the effluent by 10 minutes. At 10 min, the major component of effluent radioactivity and 20–40% of that retained in lung was unchanged arachidonate. Between 10 and 20 min of perfusion, a further small amount of radioactivity was lost in lung effluent and at 20 min the retained radioactivity showed a decrease in the proportion present as free arachidonate. Between 20 and 60 min, there was no further loss of radioactivity in effluent and no further change in the distribution in lung. Addition of albumin to the Krebs solution perfusate during the infusion of ¹⁴C-arachidonate increased effluent radioactivity to 80%, but albumin added after 10 min only caused the efflux of a small amount of radioactivity (10%). Treatment of labelled lung at 20 min with the calcium ionophore A23187 released biologically active metabolites of arachidonate but very little radioactivity. Metabolism of arachidonate, either during the infusion or after retention in lung, in rat lung was closer to that in human lung than to that in guinea-pig lung.     

Nascent lipoproteins from recirculating and nonrecirculating liver perfusions and from the hepatic Golgi apparatus of African green monkeys

Perfusate apoB-100-containing lipoproteins from the isolated, perfused livers of African green monkeys consist of significant amounts of d greater than 1.006 g/ml particles in addition to very low density lipoproteins (VLDL). Distinguishing characteristics of these perfusate lipoproteins are the relative abundance of surface lipids and deficiency of core lipids. The present studies were performed to determine the likelihood that the d greater than 1.006 g/ml perfusate lipoproteins are secretion products instead of products of post-secretory modification (e.g., lipolysis) of secreted VLDL. [14C]Leucine from the perfusate became incorporated into the apoB of each of the perfusate lipoprotein classes to a similar extent in both recirculating and nonrecirculating perfusions. When endogenously radiolabeled perfusate VLDL from one liver was recirculated through a second liver, only about 15% of the radiolabeled protein appeared in the d greater than 1.006 g/ml fraction. The particle morphology and the cholesterol and apoB distribution between VLDL and d greater than 1.006 g/ml fractions were similar in recirculating and nonrecirculating perfusions. A Golgi apparatus-rich fraction was isolated from the homogenates of fresh liver samples and the isolated Golgi VLDL and d greater than 1.006 g/ml lipoproteins exhibited morphologic evidence of extra surface material analogous to that seen in perfusate. Taken together, these data support the possibility that significant amounts of d greater than 1.006 g/ml lipoproteins, many with surface-rich properties, are nascent, secretory products of the primate liver. The low level of lecithin:cholesterol acyltransferase (LCAT) in this perfusion system appears to permit detection of these secretion products and it is significant to note that the perfusate lipoprotein profile, which is unlike that of normal plasma, is similar to that of LCAT-deficient patients.