Recognition of alpha 2-Macroglobulin by the Low Density Lipoprotein Receptor-related Protein Requires the Cooperation of Two Ligand Binding Cluster Regions

doi:10.1074/jbc.M104382200

Ideal method for primary cell transfection

Recognition of $alpha$ ₂-Macroglobulin by the Low Density Lipoprotein Receptor-related Protein Requires the Cooperation of Two Ligand Binding Cluster Regions^*

Irina Mikhailenko, Frances D. Battey, Mary Migliorini, Jose F. Ruiz, Kelley Argraves, Morvarid Moayeri, and Dudley K. Strickland

From the Department of Vascular Biology, Holland Laboratory, American Red Cross, Rockville, Maryland 20855

Received for publication, May 14, 2001, and in revised form, July 18, 2001

ABSTRACT

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The low density lipoprotein receptor-related protein (LRP) is a scavenger receptor that binds several ligands including theactivated form of the pan-proteinase inhibitor $alpha$ ₂-macroglobulin( $alpha$ ₂M*) and amyloid precursor protein, two ligands geneticallylinked to Alzheimer's disease. To delineate the contribution ofLRP to this disease, it will be necessary to identify the siteson this receptor which are responsible for recognizing these andother ligands to assist in the development of specific inhibitors.Structurally, LRP contains four clusters of cysteine-rich repeats,yet studies thus far suggest that only two of these clusters (clustersII and IV) bind ligands. Identifying binding sites within LRPfor certain ligands, such as $alpha$ ₂M*, has proven to be difficult.To accomplish this, we mapped the binding site on LRP for twoinhibitors of $alpha$ ₂M* uptake, monoclonal antibody 8G1 and an amino-terminalfragment of receptor-associated protein (RAP D1D2). Surprisingly,the inhibitors recognized different clusters of ligand bindingrepeats: 8G1 bound to repeats within cluster I, whereas the RAPfragment bound to repeats within cluster II. A recombinant LRPmini-receptor containing the repeats from cluster I along withthree ligand binding repeats from cluster II was effective inmediating the internalization of ¹²⁵I-labeled $alpha$ ₂M*. Together, these studies indicate that ligand bindingrepeats from both cluster I and II cooperate to generate a highaffinity binding site for $alpha$ ₂M*, and they suggest a strategy fordeveloping specific inhibitors to block $alpha$ ₂M* binding to LRP byidentifying molecules capable of binding repeats in clusterI.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

The low density lipoprotein receptor-related protein (LRP)¹is a member of the LDL receptor family, a multigene family of structurallyrelated endocytic receptors. LRP, like all members of the LDLreceptor gene family, consists of five common structural units:1) clusters of ligand binding cysteine-rich repeats; 2) epidermalgrowth factor (EGF) receptor like cysteine-rich repeats; 3) YWTDdomains; 4) a single membrane-spanning segment; and 5) a cytoplasmictail that harbors two NPXY motifs. The ligand binding regionsin LRP occur in four clusters (clusters I-IV) containing between2 and 11 individual ligand binding repeats. Most of the ligandsfor LRP for which the binding sites have been mapped interactwith ligand binding repeats in clusters II and IV (1-4).

The first member of this receptor family to be identified was the LDL receptor, which plays an important role in cholesterolhomeostasis (5). In contrast, other members of this gene familyseem to have more diverse functions. In the case of LRP, its biologicalrole includes a function in lipoprotein metabolism (6), inthe homeostasis of proteinases and proteinase inhibitors (7,8), in the cellular entry of viruses (9) and toxins (10),in activation of lysosomal enzymes (11), in cellular signaltransduction (12), and in the pathology of Alzheimer's disease(13).

LRP contributes to the pathology of Alzheimer's disease by influencing both the production (13) and clearance (14) ofthe $beta$ amyloid peptide (A $beta$ ). This molecule is a 40-42-amino acidpeptide that is the prominent component of senile plaques (15,16), which are a major pathological hallmark of Alzheimer'sdisease (17). A $beta$ is derived from proteolytic processing of aubiquitous transmembrane protein termed $beta$ -amyloid precursor protein(18). The association of LRP with amyloid precursor proteinisoforms containing a Kunitz-type proteinase inhibitor domainalters amyloid precursor protein processing, leading to increasedA $beta$ production (13, 19). At the same time, the A $beta$ peptide bindsavidly to LRP ligands, especially $alpha$ ₂M and the activated form ofthe molecule (termed $alpha$ ₂M*). LRP-mediated clearance of the $alpha$ ₂M*·A $beta$ complex contributes to a reduction in A $beta$ levels (14, 20).Not only does $alpha$ ₂M* appear to mediate clearance of the A $beta$ peptide,but the association of $alpha$ ₂M* with LRP on neurons also leads toan influx of calcium via N-methyl-D-aspartate receptors (12).

To delineate further the contribution of LRP to pathological processes such as Alzheimer's disease, it will be important todefine the structural basis for the $alpha$ ₂M* interaction with LRPto assist in the development of specific inhibitors of this process.Defining regions within LRP responsible for $alpha$ ₂M* binding has provento be difficult, and conflicting studies have been reported (4,21). The objective of the current investigation was to identifythe specific region on LRP responsible for binding $alpha$ ₂M*. To accomplishthis, we identified the binding sites on LRP for two inhibitorsof $alpha$ ₂M* uptake, monoclonal antibody 8G1 and an amino-terminalfragment of RAP (RAP D1D2). The studies indicate that the cooperationof ligand binding repeats from both cluster I and II is requiredfor the high affinity binding of $alpha$ ₂M* to LRP.

EXPERIMENTAL PROCEDURES

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Proteins and Antibodies-- LRP was isolated from human placenta as described by Ashcom et al. (22). Human $alpha$ ₂M was isolated from plasma and activatedwith trypsin as described (22). Human RAP and RAP fragmentsD1D2 and D4 were expressed in bacteria as fusion proteins withglutathione S-transferase and purified as described previously(23). Pro-urokinase provided by Jack Henkin (Abbott Laboratories)was activated by incubation with plasmin-Sepharose, and high molecularweight urokinase (uPA) was purified over a benzamadine-Sepharosecolumn. Plasminogen activator inhibitor type I (PAI-1) was generouslyprovided by Dan Lawrence (American Red Cross). R2629, a rabbitpolyclonal IgG against LRP, was affinity purified over LRP-Sepharoseas described (10). Monoclonal antibodies 5A6 and 8G1 have beenraised against human LRP and described previously (7). Cellsproducing the anti-myc IgG 9E10 were obtained from the AmericanType Culture Collection (Rockville), and the IgG was purifiedby chromatography on protein G-Sepharose.

Proteins were labeled with ¹²⁵I to a specific activity ranging from 2 to 10 µCi/µg protein using IODO-GEN (Pierce Chemical Co.).To generate the radiolabeled uPA·PAI-1 complex ¹²⁵I-uPA was incubated with PAI-1 (1:1.5 molar ratio) for 30 minat room temperature in Tris-buffered saline, pH 8.0. To generatethe iodinated $alpha$ ₂M·trypsin complex (designated $alpha$ ₂M*) ¹²⁵I- $alpha$ ₂M was incubated with trypsin (1:4 molar ratio) for 5 min atroom temperature, then the soybean proteinase inhibitor was added,and the ¹²⁵I- $alpha$ ₂M* was purified by size exclusionchromatography.

Solid Phase Binding Assay-- The binding of $alpha$ ₂M* to LRP immobilized on plastic was performed essentially as described earlier (23). Microtiter wellswere coated with LRP (10 µg/ml in Tris-buffered saline, pH 8.0,100 µl/well) overnight and then blocked with 3% bovine serum albuminin Tris-buffered saline. 5 nM ¹²⁵I- $alpha$ ₂M* was added to the wells in the absence or presence of theindicated antibody (300 µg/ml) and incubated for 4 h at 37 °C.After incubation the microtiter wells were washed and counted.Nonspecific binding was measured in presence of 1 µM RAP andsubtracted.

Construction of cDNAs for LRP Mini-receptors and Soluble Fragments-- cDNA of human LRP (13) was used as a template. To generate expression vectors for the soluble fragments of LRP a commercialplasmid pSecTagB (Invitrogen) was utilized. The plasmid containsIg k-chain leader sequence to ensure the secretion of expressedprotein. cDNAs encoding selected portions of LRP (see Fig. 3)were produced by polymerase chain reaction and subcloned intopSecTagB using HindIII and XhoI sites in the case of sLRP1, sLRP1a,and sLRP1b. BamHI and XhoI sites were used for subcloning of sLRP2,sLRP3, and sLRP4 fragments. sLRP1 encodes amino acids 1-172 ofmature LRP peptide. The other fragments used in this study containthe following amino acid sequences of LRP: sLRP1a, 1-786; sLRP1b,1-955; sLRP2, 787-1244; sLRP3, 2462-3004; sLRP4, 3274-3843. Recombinantproteins sLRP1, sLRP1a, and sLRP1b contain extra 13 amino acids(AAQPARRARRTKL) encoded by a polylinker sequence at their aminoterminus. SLRP2, sLRP3, and sLRP4 contain 19 amino acids (AAQPARRARRTKLGTELGS)encoded by a polylinker sequence. All soluble LRP fragments havea myc epitope and polyhistidine tag at the carboxyl terminus fordetection. The construction of cDNAs for the mini-receptors isillustrated in Fig. 4. First, a polymerase chain reaction productthat encodes the entire region from after the cluster IV of ligandbinding domains to the carboxyl terminus of LRP (residues 3844-4525)was subcloned into the XhoI and XbaI sites of pSecTagB. This plasmidwas designated pSecTagLC (light chain). Then, cDNA encoding theselected portion of LRP containing ligand binding repeats wasinserted into pSecTagLC using HindIII and XhoI sites for mini-receptorsmLRP1 and mLRP1b or BamHI and XhoI sites for mLRP2, mLRP3, andmLRP4.

Expression of Recombinant Forms of LRP-- Secreted fragments of LRP containing ligand binding domains were transiently expressed in COS-1 cells using FuGENE 6 transfectionreagent (Roche Molecular Biochemicals, Indianapolis) accordingto the manufacturer's protocol. Cells growing in 100-mm dishes(~50% confluence) were transfected in serum-containing mediumwith 30 µg of pSecTagB carrying cDNA for various LRP fragments.Cells were washed 24 h after transfection, and the medium waschanged for plain Dulbecco's modified Eagle's medium supplementedwith 1% Nutridoma^®-NS medium supplement (Roche Molecular Biochemicals). This mediumwas harvested after 48 h of incubation, subjected to immunoblotanalysis using anti-myc antibody to detect recombinant proteins,and used in further experiments. LRP mini-receptors were expressedin CHO 13-5-1 cells using FuGENE 6 transfection reagent (RocheMolecular Biochemicals) as follows. Cells were plated in six-wellplates (5 × 10⁴ cells/well) 24 h prior to the transfection. Transfections wereperformed using 2 µg of DNA/well in 1.5 ml of serum-containingmedium. 36-40 h after the beginning of transfection cells werewashed and used in the ligand internalizationexperiments.

Cellular-mediated Ligand Internalization and Degradation Assays-- Cellular internalization and degradation assays were generally conducted as described previously (24). Human foreskin fibroblastswere seeded into 12-well culture dishes (5 × 10⁴ cells/well) and grown in Dulbecco's modified Eagle's medium supplementedwith 10% bovine calf serum and penicillin/streptomycin for 2 days.Cells were washed and incubated in serum-free medium for 1 h beforethe assay. 0.4 ml of Dulbecco's modified Eagle's medium containing1% bovine serum albumin and various antibodies at selected concentrationswas added to the corresponding wells and incubated for 15 minat 37 °C. Then ¹²⁵I-labeled $alpha$ ₂M* was added to each well (2 nM final concentration).After incubation for 2 h at 37 °C, cells were washed with phosphate-bufferedsaline and detached from plastic using 0.5 mg/ml trypsin, 0.5mg/ml proteinase K, and 5 mM EDTA-containing buffer. Internalized¹²⁵I- $alpha$ ₂M* was defined as radioactivity associated with the cell pellet.Nonspecific uptake of ¹²⁵I- $alpha$ ₂M* was determined in the presence of 1 µM RAP and was subtractedfrom the total internalization. The cell numbers for each experimentalcondition were measured in parallel wells that did not containradioactivity to ensure that antibodies did not cause cell detachmentduringtreatment.

CHO 13-5-1 cells (25) transiently transfected with mini-LRP constructs were incubated for 3 h at 37 °C with ¹²⁵I-labeled ligands at the concentrations indicated in each experiment,and cellular internalization was measured as described above.Nonspecific internalization of ¹²⁵I-labeled IgG was determined in the presence of excess unlabeledantibody. Nonspecific internalization of ¹²⁵I- $alpha$ ₂M* and ¹²⁵I-labeled fragments of RAP was determined in the presence of 1µM RAP. To estimate the relative amount of different mini-receptorson the cell surface, transfected CHO 13-5-1 cells were first chilledon ice for 1 h and then incubated with ice-cold medium containing20 nM ¹²⁵I-labeled monoclonal antibody 5A6. After incubation for 2 h, cellswere washed with phosphate-buffered saline and detached from theplastic wells using 0.5 mg/ml trypsin, 0.05 mg/ml proteinase K,and 5 mM EDTA-containing buffer. Bound ¹²⁵I-5A6 was defined as radioactivity released from the cell surfaceby trypsin and proteinase K. Nonspecific binding of ¹²⁵I-labeled IgG was determined in the presence of excess unlabeledantibody andsubtracted.

To measure the cellular degradation of ¹²⁵I- $alpha$ ₂M* and ¹²⁵I-uPA·PAI-1 complexes, mouse embryonic fibroblasts were incubated with ¹²⁵I-labeled ligand in the absence or presence of RAP or the fragmentsof RAP for 6 h at 37 °C. After incubation the degraded ligandswere detected as radioactivity in the medium that is soluble in10% trichloroacetic acid. The amount of degradation products generatedin the absence of cells was also measured and subtracted fromthetotal.

RESULTS

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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS
DISCUSSION
REFERENCES

Monoclonal Antibody 8G1 Blocks Binding of $alpha$ ₂M* to LRP-- As a first step in localizing the $alpha$ ₂M* binding site in LRP, we investigated the abilities of various antibodies prepared againstLRP to block the cellular-mediated uptake of $alpha$ ₂M* (Fig. 1A). Asa positive control, rabbit polyclonal antibody R2629, which recognizesmultiple epitopes on LRP, effectively inhibited $alpha$ ₂M* uptake, whereasthe non-immune IgG had no effect on $alpha$ ₂M* internalization by thesecells. Monoclonal antibody 8G1 was also able to inhibit LRP-mediated $alpha$ ₂M* internalization in a dose-dependent manner. In contrast,monoclonal antibody 5A6 did not inhibit $alpha$ ₂M* internalization butrather seemed to enhance its uptake somewhat. Western blot analysisconfirmed our previous report (7) that monoclonal antibody8G1 recognizes the 515-kDa $alpha$ -chain of LRP to which all of theligands have been found to bind, whereas 5A6 recognizes the 85-kDa $beta$ -chain (Fig. 1B).

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Fig. 1. A, effect of anti-LRP antibodies on $alpha$ ₂M* internalization by human fibroblasts. Human foreskin fibroblasts were incubated with 10 nM ¹²⁵I- $alpha$ ₂M* for 2 h at 37 °C in the presence of anti-LRP antibodies at designated concentrations. After incubation, internalization of ¹²⁵I- $alpha$ ₂M* was measured as described under "Experimental Procedures." Results are expressed as a percentage of control, where no antibody was included. $black-triangle$ , 5A6 IgG;

, 8G1 IgG; $black-square$ , Rb2629 IgG; $down-triangle$ , non-immune mouse IgG. Each data point represents the mean of duplicate determinations. B, specificity of anti-LRP antibodies. Human foreskin fibroblast lysate (30 µg of total protein/lane) was subjected to nonreducing 4-12% SDS-gel electrophoresis and transferred to nitrocellulose. Replicate nitrocellulose strips were subjected to immunoblot analysis with 2 µg/ml of the indicated IgG.

To determine if monoclonal antibody 8G1 blocks the direct interaction between $alpha$ ₂M* and LRP, an in vitro binding assay wasemployed in which the binding of ¹²⁵I-labeled $alpha$ ₂M* to LRP immobilized on microtiter wells was measured.The results of this experiment (Fig. 2) demonstrated that monoclonalantibody 8G1 blocked the binding of $alpha$ ₂M* to LRP. In contrast,the $beta$ -subunit-specific antibody 5A6 had no effect on the bindingof $alpha$ ₂M* to LRP in this solid phase assay. Curiously, when comparingthe data from Fig. 1 with those of Fig. 2, it appears that 5A6seemed to stimulate LRP-mediated $alpha$ ₂M* uptake in cells but hadlittle effect on $alpha$ ₂M* binding to LRP immobilized on plastic. Althoughthe reason for this effect is not known, we speculate that 5A6may dimerize LRP on the cell surface, which is likely to increasethe affinity of this receptor for the multivalent ligand, $alpha$ ₂M*.

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Fig. 2. Effect of anti-LRP antibodies on $alpha$ ₂ M* binding to LRP. 5 nM ¹²⁵I- $alpha$ ₂M* was incubated for 4 h at 37°C in microtiter wells coated with 1 µg/ml LRP in the presence of the indicated antibodies at 300 µg/ml. After incubation, the wells were washed and counted. Nonspecific binding in presence of 1 µM RAP was subtracted. Each data point represents the mean of triplicate determinations.

Monoclonal Antibody 8G1 Binds to the First Cluster of Ligand Binding Repeats-- We next set out to map the region on LRP recognized by monoclonal antibody 8G1. For these experiments, a series of secretedreceptor fragments was prepared (Fig. 3A). Accumulating data demonstratethat a number of LRP ligands bind to the clusters of ligand bindingcysteine-rich repeats, so we focused on LRP fragments which containthe four clusters of ligand binding repeats (sLRP1, sLRP2, sLRP3,sLRP4). We also designed a fragment that included cluster I alongwith EGF repeats and the YWTD region (sLRP1a) and a fragment witha portion of cluster II (sLRP1b) because a similar fragment ofchicken LRP has been reported to display some $alpha$ ₂M* binding activity(26). The constructs contained a myc epitope tag at their carboxyl-terminalregion. After transfection of cells, the conditioned medium wascollected, and secreted LRP fragments were detected by immunoblottingwith anti-myc IgG (Fig. 3B, left). When the same samples wereprobed with 8G1 antibody (Fig. 3B, right), sLRP1, sLRP1a, andsLRP1b were recognized by 8G1. In contrast, sLRP2, sLRP3 and sLRP4were not recognized by 8G1. These results indicate that the 8G1binding site is located within a stretch of amino acids encompassingresidues 1-172 in the LRP sequence, which contains the first clusterof ligand binding repeats along with two EGF-like repeats. WhensLRP-containing medium was subjected to SDS-polyacrylamide gelelectrophoresis under reducing conditions prior to immunoblotting,monoclonal antibody 8G1 no longer recognized any of the LRP fragments(data not shown), indicating that the 8G1-binding epitope is notcomprised of a linear stretch of amino acids. Experiments werealso performed to determine if $alpha$ ₂M* was capable of binding tofull-length LRP or any secreted receptor fragment using a ligandblotting protocol. The ligand blot experiments failed to detect $alpha$ ₂M* binding to full-length LRP or any secreted receptor fragment,indicating that $alpha$ ₂M* binding to LRP is sensitive to the conformationof the LRP molecule.

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Fig. 3. 8G1 antibody recognizes the amino-terminal portion of LRP. A, secreted receptor fragments used in the antibody mapping study. The symbols for the various domains are indicated in the inset. B, conditioned medium from COS-1 cells transfected with the designated sLRP was subjected to nonreducing 4-12% SDS-gel electrophoresis and transferred to nitrocellulose. Replicate membranes were probed with 1 µg/ml 9E10 (left panel) and 8G1 (right panel) antibodies.

High Affinity $alpha$ ₂M* Binding to LRP Requires Ligand Binding Repeats in Both Cluster I and Cluster II-- To identify the region on LRP responsible for binding $alpha$ ₂M*, LRP mini-receptors were constructed in which various clustersof ligand binding repeats were fused with the entire $beta$ -chain containinga myc epitope at its carboxyl terminus (Fig. 4). In addition,a mini-receptor (termed mLRP1b) was also prepared which containedthe first cluster of repeats along with the first three repeatsfrom cluster II. Plasmids containing the cDNA encoding these receptorswere transfected into LRP-deficient CHO 13-5-1 cells, and theexpression and processing of the receptors were analyzed by immunoblottingwith anti-myc IgG. This revealed that all mini-receptors wereexpressed at similar levels and processed by furin (Fig. 4B, left).Immunoblotting of the same cell lysates with 8G1 (Fig. 4B, right)indicated that constructs containing the first cluster of ligandbinding repeats were recognized by 8G1, data that are consistentwith the results obtained with the soluble receptors. Further,the 8G1 blot confirmed furin processing of mLRP1 and mLRP1b because $alpha$ -chains of mature mini-receptors were readily detectable (Fig.4B, right).

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Fig. 4. Recombinant mini-receptors used in the $alpha$ ₂M* binding studies. A, schematic representation of mini LRPs shown in the comparison to the full-length endogenous LRP. The symbols for the various domains are as in Fig. 3. The site of the furin cleavage and two subunits generated upon cleavage are indicated. B, cell lysates prepared from CHO 13-5-1 transiently transfected with various mini-LRPs were subjected to nonreducing 4-12% SDS-gel electrophoresis and analyzed by Western blotting with 9E10 (left panel) or 8G1 (right panel) antibodies. Anti-myc 9E10 recognizes precursor endoplasmic reticulum and Golgi forms (labeled p) as well as $beta$ -chains of mature proteins (labeled b). The monoclonal anti-LRP 8G1 recognizes precursor endoplasmic reticulum and Golgi forms (labeled p) and $alpha$ -chains of mature proteins (labeled a).

Next, CHO 13-5-1 cells transfected with various mini-receptors were employed to measure the internalization of ¹²⁵I-labeled 8G1 (Fig. 5A) and ¹²⁵I-labeled 5A6. Cells expressing mLRP1 and mLRP1b mediated theinternalization of ¹²⁵I-labeled 8G1 (Fig. 5A), whereas cells expressing mLRP2 or LCwere unable to internalize antibody 8G1. Studies using ¹²⁵I-labeled $beta$ -chain monoclonal antibody 5A6 confirmed that bothmLRP2 and LC are effectively delivered to the cell surface, andcapable of mediating the endocytosis of this antibody (Fig. 5B),confirming that these mini-receptors are functional. We next measuredthe ability of various mini-receptors to mediate the internalizationof ¹²⁵I-labeled $alpha$ ₂M* and found that cells transfected with mLRP1b weremuch more efficient in internalizing $alpha$ ₂M* than cells expressingmLRP1, mLRP2 or LRP light chain (LC) (Fig. 6A). To correct fordifferent expression levels of mini-receptors, transfected cellswere chilled to 4 °C, and the amount of ¹²⁵I-labeled 5A6 bound to the cells was measured (Fig. 6B). Fig.6C shows the internalization of $alpha$ ₂M* adjusted to the differencein the expression levels of mini-receptors (i.e. normalized tothe amount of 5A6 IgG bound at 4 °C). The result suggests thatoptimal binding of $alpha$ ₂M* to LRP requires ligand binding repeatsfrom cluster I as well as from cluster II. In separate experiments,we also examined cells transfected with mLRP3 and mLRP4 and foundthat these mini-receptors were unable to bind and internalize $alpha$ ₂M* (data not shown).

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Fig. 5. Uptake of monoclonal antibodies 8G1 and 5A6 by CHO 13-5-1 cells transfected with mini-LRPs. CHO 13-5-1 cells transiently transfected with the indicated mini-LRP constructs were incubated for 3 h at 37 °C with 30 nM ¹²⁵I-8G1 IgG (A) or 30 nM ¹²⁵I-5A6 IgG (B). After incubation the amount of internalized ligand was determined as described under "Experimental Procedures."

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Fig. 6. Uptake of $alpha$ ₂M* by CHO 13-5-1 cells transfected with mini-LRPs. CHO 13-5-1 cells transiently transfected with indicated mini-LRP constructs were incubated for 3 h at 37 °C with 15 nM ¹²⁵I- $alpha$ ₂M* (A) or for 2 h on ice with 20 nM ¹²⁵I-5A6 IgG (B). After incubation the amount of internalized or bound ligand was determined as described under "Experimental Procedures." To compare the efficiency of $alpha$ ₂M* internalization mediated by different mini-receptors, we divided the amount of internalized $alpha$ ₂M* by the amount of 5A6 bound to the surface of the corresponding cell line (C).

The Amino-terminal Region of RAP Inhibits the LRP-mediated Internalization of $alpha$ ₂M* upon Binding to Repeats in Cluster II-- RAP is composed of four domains (27) and contains two LRP binding sites, one within the first two domains (D1D2) and onein the fourth domain (D4) (27). We tested the ability of eachof these domains to inhibit the uptake of ¹²⁵I-labeled uPA·PAI-1 complexes and ¹²⁵I-labeled $alpha$ ₂M* (Fig. 7). Both D1D2 and D4 inhibited the LRP-mediatedinternalization of ¹²⁵I-labeled uPA·PAI-1 complexes (Fig. 7A), a ligand that binds torepeats within cluster II as well as cluster IV.² In contrast to uPA·PAI-1, the internalization of $alpha$ ₂M* was onlyblocked by the D1D2 fragment of RAP, whereas D4 had no inhibitoryeffect on LRP-mediated uptake of $alpha$ ₂M* (Fig. 7B).

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Fig. 7. Effect of RAP fragments on LRP-mediated degradation of ¹²⁵I- $alpha$ ₂M* and ¹²⁵I-uPA·PAI-1. Mouse embryonic fibroblast cells were incubated with 10 nM ¹²⁵I-uPA·PAI-1 (A) or with 5 nM ¹²⁵I- $alpha$ ₂M* (B) for 6 h at 37 °C in the absence or presence of 500 nM RAP, 1 µM amino-terminal fragment of RAP D1D2, or 1 µM C-terminal fragment of RAP D4. After incubation, degradation products in the incubation medium were measured as described under "Experimental Procedures." Each data point represents the mean of triplicate determinations.

To identify the portions of LRP which bind the RAP fragments D1D2 and D4, we transfected cells with various LRP mini-receptorsand measured internalization of radiolabeled D1D2 and D4. In thesame experiment uptake of ¹²⁵I-5A6 was determined to adjust for difference in the levels ofreceptor expression. The results of this experiment are shownin Fig. 8. ¹²⁵I-Labeled D1D2 was effectively internalized by cells expressingmLRP1b and mLRP2 but not by cells expressing mLRP1 or LC (Fig.8A), indicating that the D1D2 binding site is located within threeamino-terminal ligand binding domains of the cluster II. Thus,D1D2, which binds to cluster II, can effectively compete for $alpha$ ₂M*binding. In the same experiment, D4 was also found to bind tomLRP1b (Fig. 8B), but remarkably it failed to inhibit $alpha$ ₂M* binding.

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Fig. 8. Internalization of RAP fragments mediated by mini-LRPs. CHO 13-5-1 cells were transfected with the indicated mini-LRP constructs and mock transfected. Cells were incubated with ¹²⁵I-RAP D1D2, ¹²⁵I-RAP D4, or ¹²⁵I-5A6 IgG (each at 50 nM) for 2 h at 37 °C. The amount of internalized ligand was determined as described under "Experimental Procedures," and nonspecific internalization by the mock transfected cells was subtracted. Results are expressed as a ratio of the RAP fragment internalization to the 5A6 internalization. Each data point represents the mean of duplicate determinations.

To compare $alpha$ ₂M* binding properties of full-length LRP and mLRP1b, we expressed these receptors in CHO 13-5-1 cells and measured¹²⁵I- $alpha$ ₂M* uptake in presence of excess D1D2 and D4 fragments of RAPand 8G1 IgG (Fig. 9A). Consistent with results shown earlier (Figs.1 and 7), monoclonal antibody 8G1 and D1D2 inhibited the interactionof $alpha$ ₂M* with both full-length LRP and mini-receptor mLRP1b, butD4 did not. To compare the relative affinity of $alpha$ ₂M* for LRP andmLRP1b, CHO 13-5-1 cells were transfected with full-length LRPand mLRP1b, and the transfected cells were incubated with increasingconcentrations of ¹²⁵I-labeled $alpha$ ₂M*. As expected, cells transfected with either LRPor mLRP1b showed a dose-dependent increase in $alpha$ ₂M* uptake, whichapproached saturation at higher $alpha$ ₂M* concentrations (Fig. 9B).The concentration of $alpha$ ₂M* required for half-saturation in theLRP-transfected cells was 17 nM, whereas the concentration requiredfor the mLRP1b transfected cells was 34 nM. These results indicatesimilar affinity of the mLRP1b and LRP for $alpha$ ₂M*.

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Fig. 9. Comparison of full-length LRP and mini-LRP1b on inhibitor sensitivity and $alpha$ ₂M* uptake. A, effect of RAP fragments and monoclonal antibody 8G1 on ¹²⁵I- $alpha$ ₂M* internalization mediated by full-length LRP and by mLRP1b. CHO 13-5-1 cells transfected with LRP or with mini-receptor LRP1b were incubated with 15 nM ¹²⁵I- $alpha$ ₂M* for 3 h at 37 °C in the absence or presence of 1 µM amino-terminal fragment of RAP D1D2, 1 µM carboxyl-terminal fragment of RAP D4, or 300 µg/ml monoclonal antibody 8G1. After incubation the amount of internalized ligand was determined as described under "Experimental Procedures." Each data point represents the mean of duplicate determinations. B, comparison of $alpha$ ₂M* dose response for LRP and mLRP1b. CHO 13-5-1 cells transfected with LRP, mLRP1b, or mock transfected were incubated with increasing concentrations of ¹²⁵I-labeled $alpha$ ₂M* for 2 h at 37 °C. The amount of internalized $alpha$ ₂M* was determined as described under "Experimental Procedures," and nonspecific internalization by the mock transfected cells was subtracted.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES RESULTS DISCUSSION REFERENCES

A major question that remains unanswered is how LRP can bind multiple structurally distinct ligands with such high affinity.An important component in answering this question lies in identifyingregions on LRP which recognize specific ligands. Identificationof the regions on LRP involved in recognizing $alpha$ ₂M* has provento be difficult because unlike most other LRP ligands, $alpha$ ₂M* bindingto LRP appears sensitive to LRP conformation. Previous work indicatesthat $alpha$ ₂M* binds a unique region on LRP because its binding tothis receptor is not competed with other ligands, such as apoE(28), tissue-type plasminogen activator (29), or with a Fabfragment that binds to a region within cluster II (30).

Earlier studies by Moestrup and Gliemann (31) demonstrated that a 75-kDa proteolytic fragment of LRP containing clusterII (residues 776-1399) recognized the ¹²⁵I-labeled rat $alpha$ ₁-macroglobulin light chain. Later studies, usingsurface plasmon resonance reported measurable binding of LRP fragmentscontaining either cluster II or cluster IV to $alpha$ ₂M* immobilizedon sensor chips (4). Together, these in vitro binding studiessuggest that the $alpha$ ₂M* binding site in LRP may be contained withincluster II or cluster IV. However, in contrast to these experiments,cells transfected with LRP mini-receptors containing clustersII or clusters IV failed to bind $alpha$ ₂M* or mediate its cellularinternalization (21, 32). This failure was not caused by incorrectfolding or cellular processing of these mini-receptors, as theywere fully functional in mediating the internalization of otherligands.

The objective of the current investigation was to map the binding site on LRP for $alpha$ ₂M*. Our strategy relied on the generationof fully functional LRP deletion mutants. Each mini-receptor wasappropriately processed and delivered to the cell surface andfunctioned to endocytose a monoclonal antibody recognizing anepitope on the $beta$ -subunit. We used these mini-receptors to mapthe binding sites on LRP for two inhibitors that block the LRP-mediateduptake of ¹²⁵I-labeled $alpha$ ₂M* in cells. The first inhibitor, monoclonal antibody8G1, was found to bind to a fragment of LRP containing the firsttwo ligand binding repeats, along with two EGF-type repeats. Asecond inhibitor, an amino-terminal fragment of RAP, was foundto bind to repeats within cluster II. These data suggest thatregions of both cluster I and cluster II form a high affinity $alpha$ ₂M* binding site. This was confirmed by constructing a mini-receptorcontaining ligand binding repeats within cluster I as well asthe first three ligand binding repeats of cluster II (residues1-954 of the LRP $alpha$ -chain) and demonstrating that this receptoris effective in internalizing $alpha$ ₂M*. Thus, $alpha$ ₂M* appears to be thefirst known ligand to recognize repeats within clusterI.

Human $alpha$ ₂M is a tetrameric protease inhibitor composed of four identical subunits. As a consequence of the structural transformationof $alpha$ ₂M upon formation of a complex with proteinases, the carboxyl-terminalreceptor binding domain of each subunit becomes exposed, generatingfour identical binding sites for LRP. In vitro binding of $alpha$ ₂M*to LRP (23, 31) fits a model in which high affinity (K_D= 100-500 pM) binding occurs when two domains of $alpha$ ₂M* recognizeadjacent receptors, whereas lower affinity binding (K_D= 1-10 nM) occurs when only one of the four domains binds to LRP(31). Together with the current results, these studies suggesttwo possible models for the binding of $alpha$ ₂M* to LRP (Fig. 10). Inthe first model, repeats from cluster I and II combine to forman $alpha$ ₂M* binding site (Fig. 10A), whereas in the second model (Fig.10B), one subunit of $alpha$ ₂M* recognizes repeats in cluster I, whereasanother subunit recognizes repeats in cluster II. Both modelsaccommodate the interaction of a single $alpha$ ₂M* molecule with twoLRP molecules. Currently, it is not possible to distinguish betweenthese models, but the sensitivity of $alpha$ ₂M* binding to the conformationof LRP suggests that the first model (Fig. 10A) more accuratelyreflects the binding mechanism. The models are supported by NMRmeasurements that reported a weak interaction (K_D approximatelyequal to 140 µM) between the first repeat of cluster II and thereceptor binding domain of $alpha$ ₂M* (33) and by plasmon resonancemeasurements reporting that tandems of first and second or secondand third repeats of cluster II bind $alpha$ ₂M* weakly (K_D= 20 µM) when $alpha$ ₂M* was coupled to a sensor chip (34).

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Fig. 10. Proposed models for the LRP- $alpha$ ₂M* interaction. Ligand binding repeats (shaded cylinders) in LRP are arranged in four clusters (I-IV) containing 2, 8, 10, and 11 repeats, respectively. Each cluster is surrounded by EGF-like repeats (open circles) and YWTD $beta$ -propeller domains (wavy lines). A, in this model, repeats from cluster I are proposed to be in close proximity with the amino-terminal portion of cluster II to form a high affinity binding site for one subunit of $alpha$ ₂M*. B, an alternative model in which one subunit of $alpha$ ₂M* recognizes repeats within cluster I, while another subunit recognizes repeats within the amino-terminal region of cluster II. Although not shown, both models allow for $alpha$ ₂M* interaction with adjacent receptors.

The current investigation begins to give insight into the complexities of ligand recognition by LRP. Crystallographic andNMR studies of individual ligand binding repeats of LDL receptorand LRP revealed that the sequence variability in short loop regionsof each repeat results in a unique contour surface and chargedensity for each repeat (33). The current study, along withprevious work, suggests that the ability of LRP to bind numerousstructurally distinct ligands with high affinity results fromthe presence of 31 ligand binding repeats in the molecule, forminga unique contour surface and charge distribution, and from themultiple interactions between both the ligand and receptor. Itis now apparent that certain ligands recognize different combinationsof the ligand binding repeats in a sequential fashion, whereasothers such as $alpha$ ₂M* recognize repeats from separateclusters.

Identification of regions on LRP that are important for recognizing $alpha$ ₂M* will now allow development of specific inhibitorscapable of preventing this binding. These inhibitors should beextremely useful for dissecting out the contributions of $alpha$ ₂M*in normal and pathological processes. For example, $alpha$ ₂M* associateswith LRP in neurons and induces a calcium influx via N-methyl-D-aspartatereceptors (12). The influx of calcium caused by LRP-mediatedactivation of N-methyl-D-aspartate receptor channels is likelyto impact a variety of downstream signaling cascades and may providea mechanism of altering local synaptic plasticity. Assessing thecontribution of $alpha$ ₂M* to neuronal function in vivo using an LRPantagonist such as RAP has not been possible because RAP blocksthe binding of all ligands to LRP and thus is not selective fora particular ligand. Other LRP ligands, such as tissue-type plasminogenactivator, are also implicated in neuronal function. Tissue-typePA associates with LRP, and this interaction is important forhippocampal late phase long term potentiation. Thus, definingthe physiological role of $alpha$ ₂M* and tissue-type PA in neuronalfunction will require inhibitors capable of specifically blockingtheir interaction with LRP.

$alpha$ ₂M* is also thought to promote the catabolism of the A $beta$ peptide by binding this molecule and facilitating its LRP-mediateduptake. LRP is suspected to play a dual role in Alzheimer's disease(35) by promoting both the synthesis (13) and catabolism (14)of this toxic peptide. The development of inhibitors that specificallyblock $alpha$ ₂M* binding to LRP but do not impair the interaction ofLRP with other ligands such as amyloid precursor protein willbe useful for distinguishing between the opposing roles of LRPin Alzheimer's disease and will more precisely define the physiologicalrole of this receptor in thisdisease.

FOOTNOTES

^* This work was supported in part by National Institutes of Health Grants HL50784 and HL54710 (to D. K. S.) and Scientist DevelopmentAward 0030115N from the American Heart Association (to I. M.).Thecosts of publication of this article were defrayed in part bythe payment of page charges. The article must therefore be herebymarked "advertisement" in accordance with 18 U.S.C. Section 1734solely to indicate thisfact.

To whom correspondence should be addressed: Dept. of Vascular Biology, Holland Laboratory, American Red Cross, 15601 CrabbsBranch Way, Rockville, MD 20855. Tel.: 301-738-0464; Fax: 301-738-0465;E-mail: mikhaile@usa.redcross.org.

Published, JBC Papers in Press, August 15, 2001, DOI 10.1074/jbc.M104382200

² I. Mikhailenko and D. K. Strickland, unpublishedobservations.

ABBREVIATIONS

The abbreviations used are: LRP, low density lipoprotein (LDL) receptor-related protein; sLRP, soluble receptor fragments of LRP; mLRP, LRP mini-receptors; EGF, epidermal growth factor; $alpha$ ₂M, alpha-2-macroglobulin; $alpha$ ₂M*, alpha-2-macroglobulin activated with trypsin; A $beta$ , $beta$ amyloid peptide; RAP, receptor-associated protein; D1D2, amino-terminal fragment of RAP (1-164 aminoacids); D4, carboxyl-terminal fragment of RAP (217-323 aminoacids); uPA, urokinase; PAI-1, plasminogen activator inhibitor type 1; LC, light chain; CHO, Chinese hamster ovary.

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