Human high density lipoprotein (HDL3) binding to rat liver plasma membranes

The binding of human 125I-labeled HDL3 to purified rat liver plasma membranes was studied. 125I-labeled HDL3 bound to the membranes with a dissociation constant of 10.5 micrograms protein/ml and a maximum binding of 3.45 micrograms protein/mg membrane protein. The 125I-labeled HDL3-binding activity was primarily associated with the plasma membrane fraction of the rat liver membranes. The amount of 125I-labeled HDL3 bound to the membranes was dependent on the temperature of incubation. The binding of 125I-labeled HDL3 to the rat liver plasma membranes was competitively inhibited by unlabeled human HDL3, rat HDL, HDL from nephrotic rats enriched in apolipoprotein A-I and phosphatidylcholine complexes of human apolipoprotein A-I, but not by human or rat LDL, free human apolipoprotein A-I or phosphatidylcholine vesicles. Human 125I-labeled apolipoprotein A-I complexed with egg phosphatidylcholine bound to rat liver plasma membranes with high affinity and saturability, and the binding constants were similar to those of human 125I-labeled HDL3. The 125I-labeled HDL3-binding activity of the membranes was not sensitive to pronase or phospholipase A2; however, prior treatment of the membranes with phospholipase A2 followed by pronase digestion resulted in loss of the binding activity. Heating the membranes at 100 degrees C for 30 min also resulted in an almost complete loss of the 125I-labeled HDL3-binding activity.     

The effects of human low and high density lipoproteins on the binding of rat intermediate density lipoproteins to rat liver membranes

Upon incubation with rat liver membranes, radioiodinated rat intermediate density lipoproteins (IDL) interacted with at least two binding sites having a low and a high affinity as demonstrated by the curvilinear Scatchard plots obtained from the specific binding data. The purpose of our work was to identify the nature of these binding sites. Human low density lipoproteins (LDL), contain apolipoprotein B only, and human high density lipoproteins (HDL3), containing neither apolipoprotein B nor E, were both capable of decreasing the specific binding of rat 125I-IDL. The Scatchard analysis clearly revealed that only the low affinity component was affected by the addition of these human lipoproteins. In fact, the low affinity binding component gradually decreased as the amount of human LDL or HDL3 increased in the binding assay. At a 200-fold excess of human LDL or HDL3, the low affinity binding was totally masked, and the Scatchard plot of the specific 125I-IDL binding became linear. Only the high affinity binding component was left, enabling a precise measurement of its binding parameters. In a series of competitive displacement experiments in which the binding assay contained a 200-fold excess of human LDL or HDL3, only unlabeled rat IDL effectively displaced the binding of rat 125I-IDL. We conclude that the low affinity binding of rat IDL to rat liver membranes is due to weak interactions with unspecified lipoprotein binding sites. The camouflage of these sites by human lipoproteins makes possible the study of IDL binding to the high affinity component which likely represents the combined effect of IDL binding to both the remnant and the LDL receptors.     

Characteristics of the binding of high-density lipoprotein3 by intact cells and membrane preparations of rat intestinal mucosa

We have investigated the binding of high-density lipoprotein (HDL3, d = 1.12-1.21 g/ml), and apolipoprotein E-deficient human and rat HDL, obtained by heparin-Sepharose affinity chromatography, to intact cells and membrane preparations of rat intestinal mucosal cells. Binding of 125I-labeled HDL3 to the basolateral plasma membranes was characterised by a saturable, specific process (Kd = 21 micrograms of HDL3 protein/ml, Bmax = 660 ng HDL3 protein/mg membrane protein) and E-deficient human HDL demonstrated a similar affinity for the binding site. The basolateral plasma membranes isolated from proximal and distal portion of rat small intestine showed similar binding affinities for HDL3, whereas the interaction of HDL with brush-border membranes was characterised by mainly nonspecific and nonsaturable binding. The binding of 125I-labeled HDL3 to basolateral plasma membranes was competitively inhibited by unlabeled HDL3 but less efficiently by unlabeled human LDL. The putative HDL receptor was not dependent on the presence of divalent cations but was markedly influenced by temperature and sensitive to pronase treatment. We have also demonstrated, using whole intestinal mucosal cells, that lysine and arginine-modified HDL3 inhibited binding of normal 125I-labeled HDL3 to the same extent as normal excess HDL3. These data suggest that basolateral plasma membranes of rat intestinal mucosal cells possess a specific receptor for HDL3 which contains mainly apolipoprotein A-I and A-II, and the mechanisms of recognition of HDL3 differ from those involved in binding to the B/E receptor.     

Transport of beta-very low density lipoproteins and chylomicron remnants by macrophages is mediated by the low density lipoprotein receptor pathway

The receptor-mediated uptake of rat hypercholesterolemic very low density lipoproteins (beta VLDL) and rat chylomicron remnants was studied in monolayer cultures of the J774 and P388D1 macrophage cell lines and in primary cultures of mouse peritoneal macrophages. Uptake of 125I-beta VLDL and 125I-chylomicron remnants was reduced 80-90% in the presence of high concentrations of unlabeled human low density lipoproteins (LDL). Human acetyl-LDL did not significantly compete at any concentration tested. Uptake of 125I-beta VLDL and 125I-chylomicron remnants was also competitively inhibited by specific polyclonal antibodies directed against the estrogen-induced LDL receptor of rat liver. Incubation in the presence of anti-LDL receptor IgG, but not nonimmune IgG, reduced specific uptake greater than 80%. Anti-LDL receptor IgG, 125I-beta VLDL, and 125I-chylomicron remnants bound to two protein components of apparent molecular weights 125,000 and 111,000 on nitrocellulose blots of detergent-solubilized macrophage membranes. Between 70-90% of 125I-lipoprotein binding was confined to the 125,000-Da peptide. Binding of 125I-beta VLDL and 125I-chylomicron remnants to these proteins was competitively inhibited by anti-LDL receptor antibodies. Comparison of anti-LDL receptor IgG immunoblot profiles of detergent-solubilized membranes from mouse macrophages, fibroblasts, and liver, and normal and estrogen-induced rat liver demonstrated that the immunoreactive LDL receptor of mouse cells is of a lower molecular weight than that of rat liver. Incubation of J774 cells with 1.0 micrograms of 25-hydroxycholesterol/ml plus 20 micrograms of cholesterol/ml for 48 h decreased 125I-beta VLDL uptake and immuno- and ligand blotting to the 125,000- and 111,000-Da peptides by only 25%. Taken together, these data demonstrate that uptake of beta VLDL and chylomicron remnants by macrophages is mediated by an LDL receptor that is immunologically related to the LDL receptor of rat liver.     

Role of low density lipoprotein receptor-dependent and -independent sites in binding and uptake of chylomicron remnants in rat liver

The role of the low density lipoprotein (LDL) receptor in the binding of chylomicron remnants to liver membranes and in their uptake by hepatocytes was assessed using a monospecific polyclonal antibody to the LDL receptor of the rat liver. The anti-LDL receptor antibody inhibited the binding and uptake of chylomicron remnants and LDL by the poorly differentiated rat hepatoma cell HTC 7288C as completely as did unlabeled lipoproteins. The antireceptor antibody, however, decreased binding of chylomicron remnants to liver membranes from normal rats by only about 10%. This was true for intact membranes and for solubilized reconstituted membranes and with both a crude membrane fraction as well as with purified sinusoidal membranes. Further, complete removal of the LDL receptor from solubilized membranes by immunoprecipitation with antireceptor antibody only decreased remnant binding to the reconstituted supernatant by 10% compared to solubilized, nonimmunoprecipitated membranes. Treatment of rats with ethinyl estradiol induced an increase in remnant binding by liver membranes. All of the increased binding could be inhibited by the antireceptor antibody. The LDL receptor-independent remnant binding site was not EDTA sensitive and was not affected by ethinyl estradiol treatment. LDL receptor-independent remnant binding was competed for by beta-VLDL = HDLc greater than rat LDL greater than human LDL (where VLDL is very low density lipoprotein, and HDL is high density lipoprotein). There was weak and incomplete competition by apoE-free HDL, probably due to removal of apoE from the remnant. The LDL receptor-independent remnant-binding site was also present in membranes prepared from isolated hepatocytes and had the same characteristics as the site on membranes prepared from whole liver. In contrast, when chylomicron remnants were incubated with a primary culture of rat hepatocytes, the anti-LDL receptor antibody prevented specific cell association by 84% and degradation of chylomicron remnants completely. Based on these studies, we conclude that although binding of chylomicron remnants to liver cell membranes is not dependent on the LDL receptor, their intact uptake by hepatocytes is.     

Characterization of low density lipoprotein binding to human adipocytes and adipocyte membranes

125I-labeled low density lipoprotein (LDL) binding to purified plasma membranes prepared from freshly isolated human adipocytes was saturable, specific, and displaceable by unlabeled ligand. The maximum specific binding capacity measured at saturating concentrations of 125I-LDL was 1.95 +/- 1.17 micrograms of LDL bound/mg of membrane protein (mean +/- S.D., n = 16). In contrast to cultured fibroblasts, specific binding of LDL to adipocyte membranes was calcium-independent, was not affected by EDTA or NaCl, and was not destroyed by pronase. Plasma membranes purified directly from homogenized adipose tissue also showed calcium-independent LDL specific binding (0.58 +/- 0.33 micrograms of LDL bound/mg of membrane protein, mean +/- S.D. n = 11). Specific binding, internalization, and degradation of 125I-methylated LDL was demonstrated in isolated adipocytes and competition experiments showed that native and methylated LDL interacted with adipocytes through some common recognition mechanism(s). Compared to native LDL, specific binding of methylated LDL to adipocyte membranes was significantly reduced (43%), indicating that interaction of LDL with adipocyte was dependent in part on the lysine residues of apolipoprotein B. LDL binding to adipocyte plasma membranes was also competitively inhibited by human high density lipoprotein subfractions HDL2 and HDL3. Thus, LDL metabolism in mature adipocytes appears to be regulated by mechanisms distinctly different from a variety of cultured mesenchymal cells. In addition, the ability of adipocytes to bind, internalize, and degrade significant amounts of methylated LDL supports the view that adipose tissue is involved in the metabolism of modified lipoproteins in vivo.     

Characterization of the specific binding of rat apolipoprotein E-deficient HDL to rat hepatic plasma membranes

We have used a preparation of rat liver plasma membranes to study the binding of rat apolipoprotein E-deficient HDL to rat liver. The membranes were found to bind HDL by a saturable process that was competed for by excess unlabeled HDL. The binding was temperature-dependent and was 85% receptor-mediated when incubated at 4, 22 and 37 degrees C. The affinity of the binding site for the HDL was consistent at all temperatures, while the maximum binding capacity increased at higher temperatures. The specific binding of HDL to the membranes did not require calcium and was independent of the concentration of NaCl in the media. The effect of varying the pH of the media on HDL binding was small, being 30% higher at pH 6.5 than at pH 9.0. Both rat HDL and human HDL3 were found to compete for the binding of rat HDL to the membranes, whereas rat VLDL remnants and human LDL did not compete. At 4 degrees C, complexes of dimyristoylphosphatidylcholine (DMPC) and apolipoproteins A-I, A-IV and the C apolipoproteins, but not apolipoprotein E, competed for HDL binding to the membranes. At 22 and 37 degrees C, all DMPC-apolipoprotein complexes competed to a similar extent, DMPC vesicles that contained no protein did not compete for the binding of HDL. These results suggest that the rat liver possesses a specific receptor for apolipoprotein E-deficient HDL that recognizes apolipoproteins A-I, A-IV and the C apolipoproteins as ligands.     

Evidence for a direct,nucleotide-sensitive interaction between actin and liver cell membranes

We have investigated the association of actin with membranes isolated from rat liver. A plasma membrane-enriched fraction prepared by homogenization in a low salt/CaCl2 buffer was found to contain a substantial amount of residual actin which could be removed by treatment with 1 M Na2CO3/NaHCO3, pH 10.5. Using a sedimentation binding assay that uses gelsolin to shorten actin filaments and render membrane binding saturable (Schwartz, M. A., and E. J. Luna. 1986. J. Cell Biol. 102:2067-2075), we found that membranes stripped of endogenous actin bound 125I-actin in a specific and saturable manner. Scatchard plots of binding data were linear, indicating a single class of binding sites with a Kd of 1.6 microns; 66 micrograms actin bound/mg membrane protein at saturation. Binding of actin to liver cell membranes was negligible with unstripped membranes, was competed by excess unlabeled actin, and was greatly reduced by preheating or proteolytic digestion of the membranes. Kinetic measurements showed that binding had an initial lag phase and was strongly temperature dependent. The binding of actin to liver cell membranes was also found to be competitively inhibited by ATP and other nucleotides, including the nonhydrolyzable analogue AMP-PNP. We conclude that we have reconstituted an interaction between actin and integral membrane proteins from the rat liver. This interaction exhibits a number of distinctive features which have not been observed in other actin- membrane systems.     

Binding of low-density lipoprotein and chylomicron remnants to the hepatic low-density lipoprotein receptor of dogs, rats and rabbits demonstrated by ligand blotting. Failure to detect a distinct chylomicron-remnant-binding protein by ligand blotting

In this paper, human low-density lipoprotein (LDL), rat chylomicron remnants and very-low-density lipoproteins of beta-mobility from cholesterol-fed rabbits (beta VLDL) have been shown to bind strongly to a protein present in solubilised liver membranes of rats, rabbits and dogs by ligand blotting with biotin-modified lipoproteins. This binding protein was identified as the LDL-receptor on several criteria. First, binding of the lipoproteins to the receptor was saturable and Ca2+-dependent; secondly, the apparent relative molecular mass of the binding protein (ranging from 128,000 in the rabbit, 145,000 in the rat to 147,000 in the dog) was similar to that of the purified bovine LDL receptor. Finally, binding activity was greatly increased in the livers of rats treated with oestrogen in pharmacological doses and absent from the liver of Watanabe heritable hyperlipidaemic (WHHL) rabbits that have a genetic defect in the LDL receptor. Some binding was also observed to a high-molecular-mass protein present in solubilised liver membranes of rats and rabbits, which, in rabbits at least, shared antigenic determinants with rabbit apoB and was not likely to be related to the LDL receptor as it was present in equal amounts in normal and WHHL rabbits. No evidence was obtained for a specific chylomicron remnant binding protein, distinct from the LDL receptor, whose activity could be detected in solubilised liver membranes by ligand blotting although a variety of solubilisation and fractionation conditions were employed.     

Characterization of the estrogen-induced lipoprotein receptor of rat liver

The ethinyl estradiol-induced lipoprotein receptor of rat liver was purified and characterized. Liver membranes were prepared from ethinyl estradiol-treated rats, solubilized, and subjected to DEAE chromatography. A fraction with a high specific activity for low density lipoprotein (LDL) binding was isolated and used to immunize mice. Hybridomas were prepared from their spleen cells, and a clone that secreted an IgG antibody, which cross-reacted with an ethinyl estradiol-induced protein of the same molecular weight as the bovine adrenal LDL receptor, was expanded. This antibody, designated P1B3, immunoprecipitated the induced lipoprotein receptor. P1B3 was used to purify the receptor, and a polyclonal antibody was raised against the pure protein. This antibody recognized a protein of similar molecular weight in rat liver, adult dog liver, and human skin fibroblasts, thus demonstrating that the induced rat lipoprotein receptor was related to the LDL receptor of other species. This receptor is present in normal rat liver, and its content is reduced by feeding an atherogenic diet, but not by feeding a diet containing 0.5% cholesterol. Moreover, cholestyramine supplementation of the diet did not induce the receptor on liver membranes. The polyclonal antibody could prevent the binding of LDL to liver membranes from control or ethinyl estradiol-treated rats. It decreased chylomicron remnant binding to membranes from ethinyl estradiol-treated membranes, but did not affect chylomicron remnant binding to liver membranes of untreated rats, a result compatible with the existence of a distinct receptor for these latter particles. The amount of LDL receptor-independent, specific remnant binding was the same in both control and ethinyl estradiol-treated rats. This is consistent with the concept that the remnant receptor is not regulated by this treatment. Based on the above, we conclude that the ethinyl estradiol-induced lipoprotein receptor of rat liver is biochemically and immunologically similar to the LDL receptor of other species. It is present on the liver of normal adult rats and could account for LDL as well as beta VLDL and HDLc removal. Although it may contribute to chylomicron remnant removal, there appears to be a second unrelated receptor or process which recognizes this lipoprotein.     

Characterization of low density and high density lipoprotein receptors in the rat corpus luteum and regulation by gonadotropin

Freshly prepared plasma membranes from rat corpora lutea were examined for the presence of low density lipoprotein (LDL) and high density lipoprotein (HDL) receptors by determining the specific binding of 125I-LDL and 125I-HDL. These membranes have two types of binding site for 125I-LDL, one with high affinity (Kd = 7.7 micrograms of LDL protein/ml), the other with low affinity (Kd = 213 micrograms of LDL protein/ml) and one type of binding site for 125I-HDL with Kd = 17.8 micrograms of HDL protein/ml. LDL receptor is sensitive to pronase and trypsin; HDL receptor, however, is resistant. The binding reaction was further characterized with respect to effect of time and temperature of incubation, requirement of divalent metal ion, influence of ionic strength, and binding specificity. In vivo pretreatment of rats with human choriogonadotropin (hCG) resulted in induction of both LDL and HDL receptors in a dose- and time-dependent manner when compared with saline-injected controls. The induction of lipoprotein receptors by hCG treatment is target organ-specific since the increase was seen only in the ovarian tissue. Membranes prepared from liver, kidney, and heart did not show an increase in lipoprotein receptors after hCG injection. An examination of the equilibrium dissociation constants for 125I-LDL and 125I-HDL binding after hCG administration revealed that the increase in binding activity was due to an increase in the number of binding sites rather than to a change in the binding affinity. In conclusion, rat corpus luteum possesses specific receptors for both LDL and HDL and these receptors are regulated by gonadotropins.     

Specific saturable binding of rat high-density lipoproteins to rat kidney membranes

The binding of rat 125I-labelled high-density lipoprotein (HDL) to rat kidney membranes was studied using HDL fractions varying in their apolipoprotein E content. The apolipoprotein E/apolipoprotein A-I ratio (g/g) in the HDL fractions ranged from essentially 0 to 1.5. All these HDL preparations showed the same binding characteristics. The saturation curves, measured at 0 degrees C in the presence of 2% bovine serum albumin, consisted of two components: low-affinity non-saturable binding and high-affinity binding (Kd about 40 micrograms of HDL protein/ml). Scatchard analyses of the high-affinity binding suggest a single class of non-interacting binding sites. These sites could be purified together with the plasma membrane marker enzyme 5'-nucleotidase. The binding of rat HDL to rat kidney membranes was not sensitive to high concentrations of EDTA, relatively insensitive to pronase treatment and influenced by temperature. The specific binding of rat HDL was highest at acid pH and showed an additional optimum at pH 7.5. On a total protein basis unlabelled rat VLDL competed as effectively as unlabelled rat HDL for binding of 125I-labelled rat HDL to partially purified kidney membranes. Rat LDL, purified by chromatography on concanavalin A columns and human LDL did not compete. Unlabelled human HDL was a much weaker competitor than unlabelled rat HDL and the maximal specific binding of 125I-labelled human HDL was only 10% of the value for 125I-labelled rat HDL.     

Parathyroid hormone binding sites in the brain

Parathyroid hormone (PTH) has been shown to have actions within the brain, suggesting the presence of central PTH receptors. This possibility was examined by determining the binding of ¹²⁵I-labeled [Nle^8,18,Tyr³⁴]bovine PTH to the plasma membranes of rat and rabbit brains. Specific binding of the tracer to membranes of the whole brain was time and tissue dependent, and was greater with membranes from the hypothalamus than with membranes from the cerebellum, cerebrum, or brain stem. The binding of the tracer to rat hypothalamic membranes was saturable and competitively displaced by unlabeled PTH(1–34), PTH(3–34), [Nle^8,18,Tyr³⁴]PTH(1–34), and by PTH-related protein, indicating the presence of a single class of high-affinity (dissociation constant = 2–5 nM), low-capacity (maximum binding capacity, B_max = 110–250 fmol/mg protein) binding site. The binding of radiolabeled PTH to these sites was not displaced by unrelated peptides of comparable molecular size (calcitonin, calcitonin-gene related peptide, adrenocorticotropin). The binding of PTH to these sites did not, however, appear to stimulate adenylate cyclase activity, as in peripheral PTH target sites. Thus, although these results indicate the presence of PTH receptors in the brain, these binding sites have a lower affinity than those in peripheral tissues and may utilize a different signal transduction system.     

The binding of low density lipoprotein by liver membranes in the pig.

Porcine liver membranes are capable of high affinity binding of homologous low density lipoproteins (LDL). Binding is time and temperature dependant and substrate saturable. High affinity binding sites are half saturated at 11 μg/ml lipoprotein-protein. The binding of ¹²⁵I-LDL is inhibited by unlabelled homologous LDL, very low density lipoproteins (VLDL) and high density lipoproteins (HDL) and also be human LDL and HDL, but not by unrelated proteins tested. The binding and displacement patterns with membranes from several other porcine tissues are similar to those of liver membranes. These results suggest the presence of “lipoprotein binding sites” in liver membranes which recognize structural features common to the lipoproteins and further indicate that liver membranes are not unique in their ability to bind LDL.     

Regulation of low density lipoprotein receptors by adrenocorticotropin in the adrenal gland of mice and rats in vivo

Membranes prepared from the adrenal gland of mice and rats possess high affinity binding sites that recognize 125I-labeled human low density lipoprotein (LDL). These binding sites resemble the functional LDL receptors that mediate the uptake of LDL by cultured mouse and bovine adrenal cells. The number of LDL binding sites per mg of membrane protein increased 2- to 5-fold over 24 h when mice or rats were treated with adrenocorticotropin (ACTH). In rats, this increase was accompanied by a similar ACTH-induced increase in the adrenal uptake of intravenously administered 125I-LDL, suggesting that the LDL binding sites mediate the uptake of LDL by the adrenal in the intact animal. The number of LDL binding sites on adrenal membranes rose by 5-fold when animals were rendered lipoprotein-deficient, either by treatment of mice with 4-aminopyrazolopyrimidine or by treatment of rats with 17 alpha-ethinyl estradiol. This increase was prevented when endogenous ACTH secretion was blocked by administration of dexamethasone, suggesting that ACTH was required. The current experiments suggest that LDL receptors provide one source of cholesterol for the mouse and rat adrenal in vivo and that the number of LDL receptors of this organ is regulated by ACTH.     

Inhibition of the binding of low density lipoproteins to liver membrane receptors by rat serum phosphorylcholine binding protein

Rat serum phosphorylcholine binding protein (PCBP) is characterized by its Ca2+ dependent property to bind phosphorylcholine ligand. PCBP immobilized on sepharose has been shown to selectively bind human plasma apo B and E containing lipoproteins. The present report describes an inhibitory effect of PCBP on the binding of human 125I-LDL to LDL receptors on estradiol treated rat liver membranes. Pre-incubation of liver membranes with PCBP did not affect the binding of 125I-LDL to the membranes. Gel filtration analysis of the incubation products from the LDL-receptor assay showed a concentration dependent binding of 125I-PCBP to LDL. The inhibitory effect of PCBP is likely due to the formation of LDL-PCBP complex and not due to the binding of PCBP to the LDL receptor site.     

Hormonal properties of avidin-biotinylinsulin and avidin-biotinylcorticotropin complexes

In connection with the development of affinity columns (based on the avidin-biotin interaction) for retrieval of peptide and protein hormone receptors, the hormonal properties of a number of avidin-biotinylinsulin and avidin-bioinylcorticotropin complexes were examined. Of particular interest was an evaluation of streptavidin as a ligand for the attachment of biotinylated hormones to solid supports and its possible advantage over SpHPP-avidin (S = succinoylated; pHPP = 3-(p-hydroxyphenyl)propionyl). As concerns binding kinetics using rat liver plasma membranes, streptavidin was found superior to avidin since it does not display apparently nonsaturable binding. Scatchard analyses of the binding of 125I-streptavidin, 125I-S-streptavidin and 125I-SpHPP-avidin to rat liver plasma membranes gave KD value of 6.7, 13.2, and 10.6 nM respectively. The binding was saturable and the unlabeled proteins competed with their labeled counterparts for the membrane binding sites. Biotinylinsulin, attached to either streptavidin or SpHPP-avidin was able to compete for 125I-insulin-binding sites on rat liver plasma membranes though somewhat larger concentrations of the complexes than of insulin were required to achieve comparable inhibition. The ID50 values for insulin and the biotinylinsulin complexes were 5 and 80 nM respectively. Biotinylcorticotropin was found to be a more effective activator of particulate rat adrenal adenylate cyclase when complexed with unmodified avidin than with streptavidin, S-streptavidin or SpHPP-avidin.     

Peripheral-type benzodiazepine receptors in human cerebral cortex, kidney, and colon.

The specific binding of [3H]PK 11195 and [3H]Ro 5-4864 to human cerebral cortex, kidney, and colon membranes was studied in order to determine whether peripheral type benzodiazepine receptors (PBR) characteristics located in human tissues are similar to those located in calf or rat tissues. While [3H]PK 11195 (0.05-10 nM, final concentration) bound with high affinity (KD about 2 nM) to human cerebral cortex, kidney, and colon membranes, yielding maximal numbers of binding sites of 255 +/- 23, 1908 +/- 28, and 1633 +/- 98 fmol/mg protein, respectively, the specific binding of [3H]Ro 5-4864 (1.25-40 nM, final concentration), was barely detectable (nonspecific binding about 90% of the total binding). Furthermore, unlabeled PK 11195 was two orders of magnitude more potent than unlabeled Ro 5-4864 in displacing [3H]PK 11195 specific binding from human cerebral cortex and kidney membranes. These results indicate that PBR binding characteristics located in human tissues are similar (but not identical) to those located in calf tissues, but not to those located in rat tissues.     

Binding properties of high-density lipoprotein subfractions and low-density lipoproteins to rabbit hepatocytes

Primary cultures of rabbit hepatocytes which were preincubated for 20 h in a medium containing lipoprotein-deficient serum subsequently bound, internalized and degraded 125I-labeled high-density lipoproteins2 (HDL2). The rate of degradation of HDL2 was constant in incubations from 3 to 25 h. As the concentration of HDL2 in the incubation medium was increased, binding reached saturation. At 37 degrees C, half-maximal binding (Km) was achieved at a concentration of 7.3 micrograms of HDL2 protein/ml (4.06 X 10(-8)M) and the maximum amount bound was 476 ng of HDL2 protein/mg of cell protein. At 4 degrees C, HDL2 had a Km of 18.6 micrograms protein/ml (1.03 X 10(-7)M). Unlabeled low-density lipoproteins (LDL) inhibited only at low concentrations of 125I-labeled HDL2. Quantification of 125I-labeled HDL2 binding to a specific receptor (based on incubation of cells at 4 degrees C with and without a 50-fold excess of unlabeled HDL) yielded a dissociation constant of 1.45 X 10(-7)M. Excess HDL2 inhibited the binding of both 125I-labeled HDL2 and 125I-labeled HDL3, but excess HDL3 did not affect the binding of 125I-labeled HDL3. Preincubation of hepatocytes in the presence of HDL resulted in only a 40% reduction in specific HDL2 receptors, whereas preincubation with LDL largely suppressed LDL receptors. HDL2 and LDL from control and hypercholesterolemic rabbits inhibited the degradation of 125I-labeled HDL2, but HDL3 did not. Treatment of HDL2 and LDL with cyclohexanedione eliminated their capacity to inhibit 125I-labeled HDL2 degradation, suggesting that apolipoprotein E plays a critical role in triggering the degradative process. The effect of incubation with HDL on subsequent 125I-labeled LDL binding was time-dependent: a 20 h preincubation with HDL reduced the amount of 125I-labeled LDL binding by 40%; there was a similar effect on LDL bound in 6 h but not on LDL bound in 3 h. The binding of 125I-labeled LDL to isolated liver cellular membranes demonstrated saturation kinetics at 4 degrees C and was inhibited by EDTA or excess LDL. The binding of 125I-labeled HDL2 was much lower than that of 125I-labeled LDL and was less inhibited by unlabeled lipoproteins. The binding of 125I-labeled HDL3 was not inhibited by any unlabeled lipoproteins. EDTA did not affect the binding of either HDL2 or HDL3 to isolated liver membranes. Hepatocytes incubated with [2-14C]acetate in the absence of lipoproteins incorporated more label into cellular cholesterol, nonsaponifiable lipids and total cellular lipid than hepatocytes incubated with [2-14C]acetate in the presence of any lipoprotein fraction. However, the level of 14C-labeled lipids released into the medium was higher in the presence of medium lipoproteins, indicating that the effect of those lipoproteins was on the rate of release of cellular lipids rather than on the rate of synthesis.     

Evaluation of prostaglandin-receptors in human and rat liver: interspecies differences at the prostaglandin receptor-level

The properties of PGE1-, PGE2- and iloprost (stable PGI2-analogue)-binding sites on normal human and rat liver surface cell membranes were investigated. The specific binding of [3H]PGE1 to human (rat) liver surface cell membranes could be displaced most effectively by unlabeled PGE1 (IC-50:2.5 +/- 1.7, (6.1 +/- 2.1) microM) and the specific binding of [3H]PGE2 by unlabeled PGE2 (IC-50: 1.9 +/- 0.9 (2.0 +/- 0.8) microM. The Scatchard analysis on [3H]PGE1- as well as on [3H]iloprost-binding was curvilinear whereas it was clearly linear on [3H]PGE2-binding in both the species. The high-affinity [3H]PGE1-sites showed a Bmax of 36.3 +/- 5.2 (21.3 +/- 4.3) fmol/mg protein and a Kd of 2.1 +/- 1.8 (1.9 +/- 0.7) nM, the low-affinity [3H]PGE1-sites a Bmax of 93.4 +/- 18.2 (86.1 +/- 13.2) fmol/mg protein and a Kd of 10.5 +/- 2.9 (15.1 +/- 3.2) nM. The high-affinity [3H]iloprost-sites exhibited a Bmax of 71.4 +/- 13.9 (35.9 +/- 8.2) fmol/mg protein and a Kd of 4.1 +/- 1.2 (1.7 +/- 1.8) nM, the low-affinity [3H]iloprost-sites a Bmax of 217.3 +/- 42.1 (142.9 +/- 17.8) fmol/mg protein and a Kd of 16.3 +/- 4.9 (9.2 +/- 7.2) nM. The [3H]PGE2-sites showed a Bmax of 135.4 +/- 51.9 (38.8 +/- 7.4) fmol/mg protein and a Kd of 16.2 +/- 3.2 (2.5 +/- 1.2) nM. It is assumed that prostaglandins of the E-series are promising substances in the regulation of human and rat liver function since liver cells are able to bind reasonable amounts of these substances in a high affinity manner. However, interspecies differences in the affinity of the prostaglandins to their receptor-sites make it strange to assume that the same biological findings claimed several times for the rat liver are relevant for human too.