The receptor-binding domain of human apolipoprotein E. Binding of apolipoprotein E fragments

To identify the domain of apolipoprotein E (apo-E) involved in binding to low density lipoprotein (LDL) receptors on cultured human fibroblasts, apo-E was cleaved and the fragments were tested for receptor binding activity. Two large thrombolytic peptides (residues 1-191 and 216-299) of normal apo-E3 were combined with the phospholipid dimyristoylphosphatidylcholine (DMPC) and tested for their ability to compete with 125I-LDL for binding to the LDL (apo-B,E) receptors on human fibroblasts. The NH2-terminal two-thirds (residues 1-191) of apo-E3 was as active as intact apo-E3 . DMPC, while the smaller peptide (residues 216-299) was devoid of receptor-binding activity. When apo-E3 was digested with cyanogen bromide (CNBr) and the four largest CNBr fragments were combined with DMPC and tested, only one fragment competed with 125I-LDL for binding to cultured human fibroblasts (CNBr II, residues 126-218). This fragment possessed binding activity similar to that of human LDL. The 125I-labeled CNBr II . DMPC complex also demonstrated high affinity, calcium-dependent saturable binding to solubilized bovine adrenal membranes. The binding of CNBr II . DMPC was inhibited by 1,2-cyclohexanedione modification of arginyl residues or diketene modification of lysyl residues. In addition, the CNBr II had to be combined with DMPC before it demonstrated any receptor-binding activity. Pronase treatment of the membranes abolished the ability of this fragment to bind to the apo-B,E receptors. This same basic region in the center of the molecule has been implicated as the apo-B,E receptor-binding domain not only by this study but also by other studies showing that 1) natural mutants of apo-E that display defective binding have single amino acid substitutions at residues 145, 146, or 158; and 2) the apo-E epitope of the monoclonal antibody 1D7, which inhibits apo-E binding, is centered around residues 139-146.     

Defective hepatic lipoprotein receptor binding of beta-very low density lipoproteins from type III hyperlipoproteinemic patients. Importance of apolipoprotein E

Apolipoprotein (apo-) E2 and beta-migrating very low density lipoproteins (beta-VLDL) (which were isolated from type III hyperlipoproteinemic subjects) both demonstrated defective binding to apo-E and apo-B,E receptors on dog liver membranes and to apo-B,E low density lipoproteins (LDL) receptors on fibroblasts. The defective binding activity of the apo-E2 and beta-VLDL varied from very poor to nearly normal. The ability of the beta-VLDL to interact with hepatic apo-E receptors was enhanced by the addition of normal apo-E3 to the beta-VLDL. Furthermore, cysteamine treatment of the apo-E2 in beta-VLDL enhanced binding of the beta-VLDL to both apo-E and apo-B,E receptors. The importance of apo-E in mediating the receptor binding of beta-VLDL to these receptors was confirmed by using monoclonal antibodies. The residual binding activity of beta-VLDL to apo-E and apo-B,E receptors was inhibited by greater than 90% with anti-apo-E, while the addition of anti-apo-B had little effect. The apo-B in the beta-VLDL was capable of binding to apo-B,E receptors after the hydrolysis of the beta-VLDL triglycerides with milk lipoprotein lipase. Lipase treatment yielded, two subfractions of beta-VLDL. One fraction (d = 1.02 to 1.03 g/ml) was enriched with apo-B100; the other fraction (d less than 1.006 g/ml) was enriched with apo-B48 and apo-E2. Significantly increased amounts of the apo-B100-enriched fraction bound to apo-B,E receptors. Inhibition of this binding caused by the addition of anti-apo-B indicated that the binding activity of this subfraction was mediated by apo-B100. The apo-B48-enriched fraction did not show a significant increase in receptor binding, suggesting that apo-B48 does not bind to these receptors. In a control experiment, it was shown that triglyceride-rich VLDL, which contain normal apo-E3 and apo-B100, bind significantly to both liver apo-E receptors and fibroblast apo-B,E receptors. This binding activity was inhibited by greater than 90% with anti-apo-E. Lipase hydrolysis of the VLDL did not further enhance their receptor-binding activity. These results demonstrate that apo-E, and not apo-B, is the major determinant mediating the receptor-binding activity of cholesterol-rich beta-VLDL and triglyceride-rich VLDL.     

A hepatocyte receptor for high-density lipoproteins specific for apolipoprotein A-I

Apolipoprotein (apo) E-deficient rat high-density lipoproteins (HDL) bind to isolated rat hepatocytes at 4 degrees C by a process shown to be saturable and competed for by an excess of unlabeled HDL. Uptake (binding and internalization) at 37 degrees C was also saturable and competed for by an excess of unlabeled HDL. At 37 degrees C the HDL apoprotein was degraded as evidenced by the appearance of trichloroacetic acid-soluble radioactivity in the incubation media. The binding of a constant amount of 125I-apo-E-deficient HDL was measured in the presence of increasing concentrations of various lipoproteins. HDL and dimyristoyl phosphatidylcholine (DMPC) X apo-A-I complexes decreased binding by 80 and 65%, respectively. Human low-density lipoproteins, DMPC X apo-E complexes, and DMPC vesicles alone did not compete for apo-E-deficient HDL binding. However, DMPC X apo-E complexes did compete for the binding of the total HDL fraction that contained apo-E but to a lesser extent than did DMPC X apo-A-I. DMPC X 125I-apo-A-I complexes also bound to hepatocytes, and this binding was competed for by excess HDL (70%) and DMPC X apo-A-I complexes (65%), but there was no competition for binding by DMPC vesicles or DMPC X apo-E complexes. It thus appears that hepatocytes have a specific receptor for HDL and that apo-A-I is the ligand for this receptor.     

Uptake of canine beta-very low density lipoproteins by mouse peritoneal macrophages is mediated by a low density lipoprotein receptor

The receptor on mouse peritoneal macrophages that mediates the uptake of canine beta-very low density lipoproteins (beta-VLDL) has been identified in this study as an unusual apolipoprotein (apo-) B,E(LDL) receptor. Ligand blots of Triton X-100 extracts of mouse peritoneal macrophages using 125I-beta-VLDL identified a single protein. This protein cross-reacted with antibodies against bovine apo-B,E(LDL) receptors, but its apparent Mr was approximately 5,000 less than that of the human apo-B,E(LDL) receptor. Binding studies at 4 degrees C demonstrated specific and saturable binding of low density lipoproteins (LDL), beta-VLDL, and cholesterol-induced high density lipoproteins in plasma that contain apo-E as their only protein constituent (apo-E HDLc) to mouse macrophages. Apolipoprotein E-containing lipoproteins (beta-VLDL and apo-E HDLc) bound to mouse macrophages and human fibroblasts with the same high affinity. However, LDL bound to mouse macrophages with an 18-fold lower affinity than to human fibroblasts. Mouse fibroblasts also bound LDL with a similar low affinity. Compared with the apo-B,E(LDL) receptors on human fibroblasts, the apo-B,E(LDL) receptors on mouse macrophages were resistant to down-regulation by incubation of the cells with LDL or beta-VLDL. There are three lines of evidence that an unusual apo-B,E(LDL) receptor on mouse peritoneal macrophages mediates the binding and uptake of beta-VLDL: LDL with residual apo-E removed displaced completely the 125I-beta-VLDL binding to mouse macrophages, preincubation of the mouse macrophages with apo-B,E(LDL) receptor antibody inhibited both the binding of beta-VLDL and LDL to the cells and the formation of beta-VLDL- and LDL-induced cholesteryl esters, and binding of 125I-beta-VLDL to the cells after down-regulation correlated directly with the amount of mouse macrophage apo-B,E(LDL) receptor as determined on immunoblots. This unusual receptor binds LDL poorly, but binds apo-E-containing lipoproteins with normal very high affinity and is resistant to down-regulation by extracellular cholesterol.     

Evidence that the platinum-reactive methionyl residue of the alpha 2-macroglobulin receptor recognition site is not in the carboxyl-terminal receptor binding domain

Digestion of human alpha 2-macroglobulin-methylamine (alpha 2M-CH3NH2) with papain prior to gel filtration resulted in the resolution of three distinct peaks. The material in peak I (Mr approximately 600,000) and peak II (Mr approximately 55,000) did not have any receptor binding ability as determined by in vivo clearance studies and in vitro competitive binding studies using mouse peritoneal macrophages. In contrast, the material in peak III (Mr approximately 20,000) bound to macrophage alpha 2-macroglobulin (alpha 2M) receptors with a Kd of 250 nM. This represents a 500-fold decrease in affinity relative to undigested alpha 2M-CH3NH2. Sequence analysis demonstrated that this material constituted the carboxyl-terminal fragment (COOH-terminal fragment) of alpha 2M. alpha 2M is known to possess a methionyl residue which is susceptible to modification by cis-dichlorodiammineplatinum (II) (cis-DDP) with the result being a loss of receptor binding ability by alpha 2M. For this reason, experiments were performed to determine if the platinum-reactive methionyl residue is located in the COOH-terminal receptor binding fragment of alpha 2M. The results of this investigation demonstrate that cis-DDP is not reactive with either the isolated COOH-terminal fragment or the COOH-terminal fragment isolated from alpha 2M-CH3NH2 which had been pretreated with cis-DDP. In addition, the COOH-terminal fragment did not bind to monoclonal antibody 7H11D6, a monoclonal antibody which binds to the platinum-reactive epitope of the alpha 2M-CH3NH2 receptor recognition site. In contrast, the 55-kDa fragment of alpha 2M bound approximately 1 mol platinum/mol of 55-kDa fragment and also bound to monoclonal antibody 7H11D6. Since the COOH-terminal fragment retains some receptor binding ability, the results of this investigation demonstrate that this fragment is not the complete receptor recognition site and suggest that a platinum-reactive methionyl residue located in the 55-kDa fragment of alpha 2M is another component of this site.     

Synthesis of a truncated Mr 46,000 mannose 6-phosphate receptor that is secreted and retains ligand binding.

On purification, human fibroblast collagenase breaks down into two major forms (Mr22,000 and Mr 27,000) and one minor form (Mr 25,000). The most likely mechanism is autolysis, although the presence of contaminating enzymes cannot be excluded. From N-terminal sequencing studies, the 22,000-Mr fragment contains the active site; differential binding to concanavalin A shows the 25,000-Mr fragment is a glycosylated form of the 22,000-Mr fragment. These low-Mr forms can be separated by Zn2+-chelate chromatography. An activity profile of this column, combined with data from substrate gels, indicates no activity against collagen in the 22,000-Mr and 25,000-Mr forms, but rather, activity casein and gelatin. The 27,000-Mr form has no activity. The 22,000/25,000-Mr form can act as an activator for collagenase in a similar way to that reported for stromelysin. The activity of the 22,000/25,000-Mr form is not inhibited by the tissue inhibitor of metalloproteinases (TIMP). The 27,000-Mr C-terminal part of the collagenase molecule therefore appears to be important in maintaining the substrate-specificity of the enzyme, and also plays a role in the binding of TIMP.     

Isolation and characterization of the apolipoprotein E receptor from canine and human liver

Previous results have demonstrated that liver membranes possess two distinct lipoprotein receptors: a low density lipoprotein (LDL) receptor that binds lipoproteins containing either apolipoprotein (apo-) B or apo-E, and an apo-E-specific receptor that binds apo-E-containing lipoproteins, but not the apo-B-containing LDL. This study reports the isolation and purification of apo-B,E(LDL) and apo-E receptors from canine and human liver membranes. The receptors were solubilized with the zwitterionic detergent 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate and were partially purified by DEAE-cellulose chromatography. The apo-B,E(LDL) receptor was isolated by affinity chromatography on LDL-Sepharose. The apo-E receptor, which did not bind to the LDL-Sepharose column, was then purified by using an HDLc (cholesterol-induced high density lipoprotein)-Sepharose affinity column and an immunoaffinity column. Characterization of the receptors revealed that the hepatic apo-B,E(LDL) receptor is similar to the extrahepatic LDL receptor with an apparent Mr = 130,000 on non-reducing sodium dodecyl sulfate-polyacrylamide gels. The apo-E receptor was found to be distinct from the apo-B,E(LDL) receptor, with an apparent Mr = 56,000. The purified apo-E receptor displayed Ca2+-dependent binding to apo-E-containing lipoproteins and did not bind to LDL or chemically modified apo-E HDLc. Antibodies raised against the apo-B,E(LDL) receptor cross-reacted with the apo-E receptor. However, an antibody prepared against the apo-E receptor did not react with the apo-B,E(LDL) receptor. The apo-E receptor also differed from the apo-B,E(LDL) receptor in amino acid composition, indicating that the apo-E receptor and the apo-B,E(LDL) receptor are two distinct proteins. Immunoblot characterization with anti-apo-E receptor immunoglobulin G indicated that the apo-E receptor is present in the hepatic membranes of man, dogs, rats, and mice and is localized to the rat liver parenchymal cells.     

Obligatory role of cholesterol and apolipoprotein E in the formation of large cholesterol-enriched and receptor-active high density lipoproteins

The formation of large cholesterol-enriched high density lipoproteins (HDL1/HDLc) from typical HDL3 requires lecithin:cholesterol acyltransferase activity, additional cholesterol, and a source of apolipoprotein (apo-) E. The present study explores the role of apo-E in promoting HDL1/HDLc formation and in imparting to these lipoprotein particles the ability to interact with the apo-B,E(low density lipoprotein (LDL] receptor. Incubation of normal canine serum with cholesterol-loaded mouse peritoneal macrophages resulted in the formation of HDL1/HDLc that competed with 125I-LDL for binding to the apo-B,E(LDL) receptors on cultured human fibroblasts. Cholesterol efflux from macrophages was necessary because incubation of normal canine serum with nonloaded macrophages did not cause HDL1/HDLc formation. However, cholesterol delivery to the serum was not sufficient to result in HDL1/HDLc formation. Apolipoprotein E had to be available. Incubation of apo-E-depleted canine serum with cholesterol-loaded J774 cells, a macrophage cell line that does not synthesize apo-E, demonstrated that no HDL1/HDLc formation was detected even in the presence of significant cholesterol efflux. However, addition of exogenous apo-E to the serum during the incubation with cholesterol-loaded J744 cells promoted the formation of large receptor-active HDL1/HDLc. The receptor binding activity of these particles produced in vitro correlated with the amount of apo-E incorporated into the HDL1/HDLc. Apolipoproteins A-I and C-III were ineffective in promoting HDL1/HDLc formation; thus, apo-E was unique in allowing HDL1/HDLc formation. These results demonstrate that when lecithin:cholesterol acyltransferase activity, cholesterol, and apo-E are present in serum, typical HDL can be transformed in vitro into large cholesterol-rich HDL1/HDLc that are capable of binding to lipoprotein receptors.     

Subunit structure of the dihydrolipoyl transacylase component of branched-chain alpha-keto acid dehydrogenase complex from bovine liver. Mapping of the lipoyl-bearing domain by limited proteolysis

To characterize the lipoyl-bearing domain of the dihydrolipoyl transacylase (E2) component, purified branched-chain alpha-keto acid dehydrogenase complex from bovine liver was reductively acylated with [U-14C] alpha-ketoisovalerate in the presence of thiamin pyrophosphate and N-ethylmaleimide. Digestion of the modified complex with increasing concentrations of trypsin sequentially cleaved the E2 polypeptide chain (Mr = 52,000) into five radiolabeled lipoyl-containing fragments in the order of L1 (Mr = 28,000), L2 (Mr = 24,500), L3 (Mr = 21,000), L4 (Mr = 15,000) to L5 (Mr = 14,000) as determined by the autoradiography of sodium dodecyl sulfate-polyacrylamide gel. In addition, a lipoate-free inner E2 core consisting of fragment A (Mr = 26,000) and fragment B (Mr = 22,000) was produced. Fragment A contains the active site for transacylation reaction and fragment B is the subunit-binding domain. Fragment L5 and fragment B were stable and resistant to further tryptic digestion. Mouse antiserum against E2 reacted only with fragments L1, L2, and L3, and did not bind fragments L4, L5, A, and B as judged by immunoblotting analysis. The anti-E2 serum strongly inhibited the overall reaction catalyzed by the complex, but was without effect on the transacylation activity of E2. Measurement of incorporation of [1-14C]isobutyryl groups into the E2 subunit indicated the presence of 1 lipoyl residue/E2 chain. Based on the above data, a model is proposed in which the lipoyl-bearing domain is connected to the inner E2 core via a trypsin-sensitive hinge. The lipoyl-bearing domain contains five consecutive tryptic sites (L1 to L5), with the L1 site in the hinge region, and the L5 site next to the terminal lipoyl-binding sequence. An exposed and antigenic region is located between L1 and L4 tryptic sites of the lipoyl-bearing domain. The region accounts for about 24% of the E2 chain length. Binding of antibodies to this region probably impairs the mobility of the lipoyl-containing polypeptide, resulting in an interruption of the active-site interactions that are necessary for the overall reaction. The lack of antigenicity and resistance to tryptic digestion indicate a highly folded conformation for fragment L5, the limit polypeptide carrying the single lipoyl residue.     

Human apolipoprotein E. Determination of the heparin binding sites of apolipoprotein E3

The interaction of human apolipoprotein (apo-) E3 with heparin was examined using heparin-Sepharose as a model system. The approach taken to determine the region of apo-E that is responsible for binding to heparin was to identify apo-E monoclonal antibodies that inhibited heparin binding, to determine the epitopes of the inhibiting antibodies, and finally to examine the heparin binding of fragments containing the inhibiting antibody epitopes. Three antibodies, designated 1D7, 6C5, and 3H1, were found to inhibit binding, suggesting that multiple heparin binding sites were present on apo-E. The epitopes of the inhibiting antibodies were determined by immunoblot analysis of synthetic or proteolytic fragments of apo-E. Measurement of the heparin binding activity of fragments containing epitopes of the inhibiting antibodies demonstrated that apo-E3 contains two heparin binding sites. The first site is located in the vicinity of residues 142-147 and coincides with the 1D7 epitope. The second binding site is contained in the carboxyl-terminal region of apo-E and is inhibited by 3H1, the epitope of which is located between residues 243 and 272. The epitope of the third inhibiting antibody, 6C5, is located at the amino terminus of apo-E; however, this antibody inhibits the second heparin binding site located in the carboxyl-terminal region. A head-to-tail association of apo-E, in which the 6C5 epitope and the second heparin binding site would be in close proximity, is proposed to account for this observation. In the lipid-free state both heparin binding sites on apo-E are expressed; however, when apo-E is complexed to phospholipid or on the surface of a lipoprotein particle, only the first binding site (residues 142-147) is expressed.     

Purification of a small receptor-binding peptide from the central region of the colicin E1 molecule

An Mr = 16,000 receptor-binding fragment of colicin E1 has been obtained by cyanogen bromide digestion of colicin E1. The purified 16-kDa fragment shows binding properties similar to those of an Mr = 38,000 colicin E1 receptor-binding fragment generated by thermolysin treatment. Treatment of the 38-kDa fragment with cyanogen bromide also yields the 16-kDa fragment. By comparing the NH2-terminal amino acid sequence of the 16-kDa fragment with the known colicin E1 sequence, the receptor-binding fragment can be shown to occupy the central region of the colicin molecule, extending from residue 231 to 370. It is inferred that the 16-kDa fragment binds efficiently to the colicin receptor because it is able to protect sensitive cells against the lethal effects of colicins E1 and E2 and, when pre-adsorbed to the cell, to physically displace colicin E1. Unlike the 38-kDa receptor-binding fragment, the 16-kDa fragment was found to be devoid of channel-forming ability previously shown to be associated with the COOH-terminal region of the colicin E1 polypeptide.     

Metal and phospholipid binding properties of partially carboxylated human prothrombin variants

To study the specific role of gamma-carboxyglutamic acid (Gla) residues in prothrombin, we have isolated a series of partially carboxylated prothrombin variants from a patient with a hereditary defect in vitamin K-dependent carboxylation (Goldsmith, G. H., Pence, R. E., Ratnoff, O. D., Adelstein, D. A., and Furie, B. (1982) J. Clin. Invest. 69, 1253-1260). The three variant prothrombins, purified by DEAE-Sephacel, immunoaffinity chromatography, and preparative gel electrophoresis, were indistinguishable from prothrombin in molecular weight, amino acid composition, and NH2-terminal amino acid sequence, with the exception of Gla residues. Variant prothrombin 1, with 8 Gla residues, had 66% of the coagulant activity of prothrombin, one high affinity metal-binding site (Kd = 15 nM), and three lower affinity sites (Kd = 2.7 microM); prothrombin contained two high affinity (36 nM) and four lower affinity sites (Kd = 1 microM). Ca(II) induced a 23% decrease in the intrinsic fluorescence of variant prothrombin 1 fragment 1, compared to a 35% decrease in that of prothrombin fragment 1. The phospholipid binding activity of variant prothrombin 1 was 44% that of prothrombin. Variant prothrombin 2 and variant prothrombin 3, with 4 and 6 Gla residues, respectively, had about 5% of prothrombin coagulant activity and a single high affinity and two lower affinity metal-binding sites and exhibited no phospholipid binding activity. Variant prothrombin 3 fragment 1 and variant prothrombin 2 fragment 1 demonstrated 18 and 13% of Ca(II)-induced fluorescence quenching, respectively. Abnormal prothrombin, with 1 Gla residue, had 8% of prothrombin coagulant activity, a single lower affinity (1 microM) metal-binding site, and 13% Ca(II)-induced fluorescence quenching of the fragment 1 species and did not bind to phospholipid. These results indicate that Gla residues define the metal binding properties of prothrombin. Most, if not all, of the Gla residues are required for complete prothrombin function, and the prothrombin coagulant activity correlates to the phospholipid binding activity of the prothrombin species.     

Binding of chylomicron remnants and beta-very low density lipoproteins to hepatic and extrahepatic lipoprotein receptors. A process independent of apolipoprotein B48

The ability of apolipoprotein (apo-) B48 to interact with lipoprotein receptors was investigated using three different types of lipoproteins. First, canine chylomicron remnants, which contained apo-B48 as their primary apoprotein constituent, were generated by the hydrolysis of chylomicrons with milk lipoprotein lipase. These apo-B48-containing chylomicron remnants are deficient in apo-E and reacted very poorly with apo-E receptors on adult dog liver membranes and the low density lipoprotein (apo-B,E) receptors on human fibroblasts. Addition of normal human apo-E3 restored the receptor binding activity of these lipoproteins. Second, beta-very low density lipoproteins (beta-VLDL) from cholesterol-fed dogs were subfractionated into distinct classes containing apo-E along with either apo-B48 or apo-B100. Both classes bound to the apo-B,E and apo-E receptors. Their binding was almost completely mediated by apo-E, as evidenced by the ability of the anti-apo-E to inhibit the receptor interaction. Third, beta-VLDL from type III hyperlipoproteinemic patients were subfractionated by immunoaffinity chromatography into lipoproteins containing apo-E plus either apo-B48 or apo-B100. Both subfractions bound poorly to apo-B,E and apo-E receptors due to the presence of defective apo-E2. However, the residual binding of the apo-B48-containing and apo-B100-containing human beta-VLDL was inhibited by the anti-apo-E. After lipase hydrolysis, apo-B100 became a more prominant determinant responsible for mediating receptor binding to the apo-B,E receptor. By contrast, lipase hydrolysis did not increase the binding activity of the apo-B48-containing beta-VLDL. These results indicate that apo-B48 does not play a direct role in mediating the interaction of lipoproteins with receptors on fibroblasts or liver membranes.     

Low-density lipoprotein receptor binding determinants switch from apolipoprotein E to apolipoprotein B during conversion of hypertriglyceridemic very-low-density lipoprotein to low-density lipoproteins

Using thrombin and trypsin as probes, we determined: first, that low-density lipoprotein (LDL) receptor binding determinants switch from apolipoprotein (apo) E to apo-B within the very-low-density lipoprotein (VLDL) Sf 20-60 region of the metabolic cascade from VLDL1 (Sf 100-400) of hypertriglyceridemic (HTG) human subjects to LDL. Second, two different conformations of apo-E exist in HTG-VLDL Sf greater than 60, one accessible (greater than or equal to 1 mol/mol of particle) and one inaccessible (1-2 mol/mol) to both thrombin and the LDL receptor; normal VLDL (Sf greater than 60) have only the inaccessible conformation and therefore do not bind to the LDL receptor. Third, thrombin degrades apo-B into large fragments, three of which have electrophoretic mobilities similar to B-48, B-74, and B-26; this, however, has no effect on apo-B-mediated receptor binding. Fibroblast studies showed that thrombin could abolish receptor uptake of HTG-VLDL1 and HTG-VLDL2 (Sf 60-100), had little or no effect on HTG-VLDL3 (Sf 20-60), and no effect on uptake of intermediate-density lipoprotein (IDL) or LDL. Trypsin abolished the binding of HTG-VLDL1 and HTG-VLDL2, reduced that of HTG-VLDL3, but had little to no effect on IDL or LDL binding. Immunochemical techniques revealed that thrombin cleaved some apo-E into the E-22 and E-12 fragments; after trypsin treatment no apo-E was detected in any HTG-lipoprotein. Normal VLDL subclasses contained less apo-E than the corresponding HTG-VLDL subclasses and it was not cleaved by thrombin. Apo-B immunoreactivities of VLDL subclasses were not significantly changed after treatment with thrombin, although thrombin cleaved some of the B-100 of each VLDL subclass, and all apo-B in IDL and LDL, into 4-6 major large fragments. Trypsin converted all of the apo-B of each lipoprotein into smaller fragments (Mr less than 100,000). We conclude that apo-E of the thrombin-accessible conformation mediates uptake of HTG-VLDL1 and HTG-VLDL2 but that apo-B alone is sufficient to mediate receptor binding of IDL and LDL; the switch from apo-E to apo-B as the primary or sufficient binding determinant occurs within the VLDL3 (Sf 20-60) region of the metabolic cascade, where receptor binding first appears in VLDL subclasses from normal subjects.     

Cysteamine selectively enhances neuropeptide Y2 receptor binding activity.

Affinity labeling of [125I]NPY to the bovine hippocampal NPY receptor has revealed a 50 kDa specific binding protein, the Y2 receptor. Cysteamine (10 microM - 10 mM) specifically enhanced NPY specific labeling of the Y2 receptor without affecting cross-linking efficiency. Several structurally related agents, including reduced glutathione, cysteine, beta-mercaptoethanol and ethanolamine, were without effect on receptor binding. The enhancement of binding by cysteamine could be reversed by washing the membranes. These studies suggest that cysteamine may change the conformation of the NPY Y2 receptor and increase its binding activity.     

The functional characteristics of a human apolipoprotein E variant (cysteine at residue 142) may explain its association with dominant expression of type III hyperlipoproteinemia.

Type III hyperlipoproteinemia typically is associated with homozygosity for apolipoprotein (apo) E2(Arg158----Cys). Dominant expression of type III hyperlipoproteinemia associated with apoE phenotype E3/3 is caused by heterozygosity for a human apoE variant, apoE3(Cys112----Arg, Arg142----Cys). However, this apoE3 variant was not separable from the normal apoE3 in these patients' plasma because the two proteins have identical amino acid composition, charge, and molecular weight. Therefore, to determine the functional characteristics of this protein, we used recombinant DNA techniques to produce this apoE variant in bacteria. We also produced a non-naturally occurring variant, apoE(Arg142----Cys), that had only the cysteine substituted at residue 142. These two apoE variants were purified from cell lysates of the transfected Escherichia coli by ultracentrifugal flotation in the presence of phospholipid, by gel filtration chromatography, and by heparin-Sepharose chromatography. Both Cys142 apoE variants bound to lipoprotein receptors on human fibroblasts with only about 20% of normal binding activity. Therefore, cysteine at residue 142, not arginine at residue 112, is responsible for the decreased receptor binding activity of the variants. Cysteamine treatment and removal of the carboxyl-terminal domain had little effect on the binding activity, whereas both modulate the receptor binding activity of apoE2(Arg158----Cys). The mutation at residue 142 decreased the binding activity of apoE to both heparin and the monoclonal antibody 1D7 (this antibody inhibits receptor binding of apoE), whereas apoE2(Arg158----Cys), which is associated with recessive expression of type III hyperlipoproteinemia, binds normally to both. The Arg112, Cys142 variant predominantes 3:1 over normal apoE3 in the very low density lipoproteins of plasma from an affected subject, as assessed by differential reactivity with the antibody 1D7. The unique combination of functional properties of the Arg112, Cys142 variant provides a possible explanation for its association with dominant expression of type III hyperlipoproteinemia.     

Subunit structure of the dihydrolipoyl transacylase component of branched-chain alpha-keto acid dehydrogenase complex from bovine liver. Characterization of the inner transacylase core

Limited proteolysis has been used to probe the subunit structure (Mr = 52,000) of the dihydrolipoyl transacylase (E2) component of the branched-chain alpha-keto acid dehydrogenase complex from bovine liver. Digestion of the complex at 0 degrees C with a low concentration of trypsin produces an inner E2 core that retains the activity for the transacylation reaction and is completely dissociated from the decarboxylase (E1) component. The trypsinized E2 maintains the highly assembled structure and migrates faster than the native E2 in the Sepharose 4B column. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis shows that the inner E2 core consists of two lipoate-free tryptic fragments, i.e. fragment A and fragment B with Mr = 26,000 and 22,000, respectively. Both fragments apparently fail to bind the E1 component. Fragment A is converted into fragment B by increasing trypsin concentrations. Fragment B is a stable limit polypeptide containing the intersubunit-binding sites for E2. The assemblage of fragment B confers the cubelike appearance of the inner E2 core in electron micrographs. Activity measurements indicate that the larger fragment A, but not fragment B, possesses transacylation activity. It is likely that a critical portion of the active site is present in the 4,000-dalton fragment that is lost during the conversion of fragment A to B.     

Steroid binding activity is retained in a 16-kDa fragment of the steroid binding domain of rat glucocorticoid receptors

The steroid binding domain of the rat glucocorticoid receptor is considered as extending from amino acids 550 to 795. However, such a synthetic protein (i.e. amino acids 547-795; Mr approximately 31,000) has been reported to show very little affinity for the potent synthetic glucocorticoid dexamethasone. We now disclose that digestion of steroid-free rat glucocorticoid receptors with low concentrations of trypsin yields a single species, of Mr = 16,000, that is specifically labeled by dexamethasone 21-mesylate. This 16-kDa fragment retains high affinity binding for [3H]dexamethasone that is only approximately 23-fold lower than that seen with the intact 98-kDa receptor. Analysis of the protease digestion patterns obtained both with trypsin and with lysylendopeptidase C allowed us to deduce the proteolytic cleavage maps of the receptor with these enzymes. From these protease maps, the sequence of the 16-kDa fragment was identified as being threonine 537 to arginine 673. These results show that glucocorticoid receptor fragments smaller than 34 kDa do bind steroids and that the amino acids Thr537-Arg673 constitute a core sequence for ligand binding within the larger steroid binding domain. The much slower kinetics in generating the 16-kDa fragment from affinity-labeled receptors suggests that steroid binding causes a conformation change in the receptor near the cleavage sites.     

Crystallization and preliminary x-ray diffraction study of synthetic apolipoprotein E fragment (residues 129-169)

Apolipoprotein E is a plasma protein comprised of a lipid binding region (which together with other apoproteins maintains the structure of lipoprotein particles) and a receptor binding domain (which interacts with cellular receptors for control of triglyceride and cholesterol metabolism). A peptide, comprising residues 129-169 of human apolipoprotein E, which contains both a putative lipid-binding region and receptor binding domain, has been synthesized by solid phase techniques. Diffraction quality crystals of the synthetic apolipoprotein E fragment129-169 have been obtained at room temperature by vapor diffusion with polyethylene glycol in the presence of the nonionic detergent beta-octylglucoside. The crystals have been characterized with x-radiation as orthorhombic, space group I222 or I2(1)2(1)2(1), with unit cell dimensions a = 61.91, b = 30.84, and c = 42.79 A. There are eight molecules per unit cell, with one molecule (Mr = 4771) in each asymmetric unit. Precession photographs show that crystals diffract beyond 2.7-A resolution and are stable in the x-ray beam at room temperature for at least 200 h; thus, they can be used to collect three-dimensional data for a detailed crystallographic analysis.     

Purification of insulin receptor with full binding activity

Insulin receptor was purified 2400-fold with an overall yield of 40% from human placental membranes by affinity chromatography on wheat germ agglutinin-Sepharose and insulin-Sepharose. The receptor was eluted from insulin-Sepharose using mild conditions, eliminating urea, so that it was stable and retained full insulin-binding activity. Chromatofocusing and gel filtration analysis indicated that the receptor preparation was apparently pure. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed three high molecular weight protein bands with Mr = 320,000, 300,000, and 270,000 under nonreducing conditions and two major protein bands with Mr = 135,000 and 90,000 under reducing conditions. The purified receptor showed a curvilinear Scatchard plot with maximum insulin binding of 28.5 micrograms per mg of protein. In comparison, the receptor eluted from insulin-Sepharose with previously used conditions in the presence of urea resulted in maximum insulin binding of only 6 micrograms per mg of protein. This indicates that a 4-to 5-fold increase in specific activity can be obtained by using the new elution conditions.