Identification of a Lipoprotein Lipase Cofactor-binding Site by Chemical Cross-linking and Transfer of Apolipoprotein C-II-responsive Lipolysis from Lipoprotein Lipase to Hepatic Lipase*

Trina L. McIlhargey {ddagger} §, Yingying Yang {ddagger}, Howard Wong ¶ || ** and John S. Hill {ddagger} {ddagger}{ddagger}

From the {ddagger}University of British Columbia McDonald Research Laboratories/iCAPTUR4E Centre, Department of Pathology and Laboratory Medicine, St. Paul's Hospital, and the University of British Columbia, Vancouver, British Columbia V6Z 1Y6, Canada, the Department of Veterans Affairs, Greater Los Angeles Healthcare System, Los Angeles, California 90073, and the ||Department of Medicine, University of California, Los Angeles, California 90095

Received for publication, January 10, 2003 , and in revised form, February 19, 2003.


    ABSTRACT
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
To localize the regions of lipoprotein lipase (LPL) that are responsive to activation by apoC-II, an apoC-II peptide fragment was cross-linked to bovine LPL. Following chemical hydrolysis and peptide separation, a specific fragment of LPL (residues 65–86) was identified to interact with apoC-II. The fragment contains regions of amino acid sequence dissimilarity compared with hepatic lipase (HL), a member of the same gene family that is not responsive to apoC-II. Using site-directed mutagenesis, two sets of chimeras were created in which the two regions of human LPL (residues 65–68 and 73–79) were exchanged with the corresponding human HL sequences. The chimeras consisted of an HL backbone with the suspected LPL regions replacing the corresponding HL sequences either individually (HLLPL-(65–68) and HLLPL-(73–79)) or together (HLLPLD). Similarly, LPL chimeras were created in which the candidate regions were replaced with the corresponding HL sequences (LPLHL-(77–80), LPLHL-(85–91), and LPLHLD). Using a synthetic triolein substrate, the lipase activity of the purified enzymes was measured in the presence and absence of apoC-II. Addition of apoC-II to HLLPL-(65–68) and HLLPL-(73–79) did not significantly alter their enzyme activity. However, the activity of HLLPLD increased ~5-fold in the presence of apoC-II compared with an increase in native LPL activity of ~11-fold. Addition of apoC-II to LPLHL-(77–80) resulted in ~10-fold activation, whereas only ~6- and ~4-fold activation of enzyme activity was observed in LPLHL-(85–91) and LPLHLD, respectively. In summary, our results have identified 11 amino acid residues in the N-terminal domain of LPL (residues 65–68 and 73–79) that appear to act cooperatively to enable substantial activation of human LPL by apoC-II.


    INTRODUCTION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Hepatic lipase (HL)1 and lipoprotein lipase (LPL) are members of the same lipase gene family, along with pancreatic lipase, the pancreatic lipase-related lipases, endothelial lipase, and phosphatidylserine-specific phospholipase A1 (16). Through their ability to hydrolyze triglycerides and phospholipids in a variety of circulating plasma lipoproteins, including chylomicrons and very low, intermediate, and high density lipoproteins, HL and LPL greatly influence lipid metabolism (79). HL and LPL are associated with cell surfaces through an interaction with heparan sulfate proteoglycans and are thought to possess non-catalytic functions associated with the binding and clearance of various lipoproteins (1013). HL and LPL share a number of functional domains such as the Ser-Asp-His catalytic triad, heparin-binding domain, lid region, and lipid- and receptor-binding domains (15). Based on their similarity of lipolytic function, amino acid homology, and conservation of disulfide bridges, it is believed that HL and LPL share a similar structure (16). Despite these similarities, however, differences remain in important enzyme characteristics such as relative heparin affinity, substrate specificity, and cofactor requirements.

Unlike HL, LPL requires a specific cofactor, apoC-II, to hydrolyze triglycerides in chylomicrons (17, 18). The importance of apoC-II for LPL function is emphasized by the observation of a significant accumulation of triglycerides in patients who have an inherited defect of the apoC-II gene (19). Initially, the study of chimeric lipases (20, 21) suggested that a region in the N-terminal domain of LPL was responsible for cofactor activation because enzymes containing the N-terminal domain of LPL and the C-terminal domain of HL were still able to be activated by apoC-II. However, these chimeric enzymes were not activated by apoC-II to the same extent as native LPL. More recently, we reported that the 60 C-terminal amino acids of LPL also participate in apoC-II activation (22), suggesting that regions in the N-terminal domain alone are not sufficient to achieve optimal activation. These results are more easily interpreted in the context of a head-to-tail dimer model (15, 20, 2325), which supports the hypothesis that apoC-II interacts simultaneously with regions located in the N- and C-terminal domains of opposing subunits that make up an LPL dimer (22).

To identify specific LPL amino acid residues that are responsive to cofactor, chemical cross-linking of apoC-II to LPL was undertaken. Cross-linking experiments identified a region from the N-terminal domain of LPL that interacted with apoC-II and whose role in activation was determined using chimeric lipases. The LPL fragment contains two candidate regions, one composed of 4 amino acids and the other of 7, that differ from HL, a highly related but cofactor-unresponsive lipase. A series of chimeras were constructed with the variable regions exchanged between the two lipases, and apoC-II responsiveness was determined. The results suggest that LPL residues 65–68 and 73–79 cooperate in cofactor activation and, moreover, that the functional responsiveness imparted by these LPL residues can be translocated to HL.


    EXPERIMENTAL PROCEDURES
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Cross-linking of ApoC-II and LPL
Overall Strategy—A fragment of human apoC-II spanning residues 44–79 (apoC-II-(44–79)) was chemically cross-linked to purified bovine LPL (Sigma). The mixture was reduced and incubated with o-iodosobenzoic acid, which cleaves proteins at tryptophan and tyrosine residues (24, 25). o-Iodosobenzoic acid-generated peptide fragments were separated on SDS-polyacrylamide gels and identified based on their size and sequence.

Step 1—The cross-linker reagent sulfosuccinimidyl-2-(p-azidosalicylamido)ethyl 1,3'-dithiopropionate (SASD) was iodinated using IODO-GEN (Pierce) under conditions recommended by the manufacturer. IODO-GEN (1 mg) was dried in microcentrifuge tubes, and SASD was added (1 mg in 1 ml of 100 mM NaPO4, pH 7.2) together with sodium iodide (100 µCi) and mixed briefly (2 min). The reaction mixture was removed from the tube and desalted to separate unbound radioisotope.

Step 2—A cofactor·cross-linker complex composed of apoC-II-(44–79) (100 µM in 100 mM NaPO4, pH 7.2) linked to the iodinated cross-linking reagent SASD was created (Fig. 1). The photolabile azido group in SASD required all steps to be carried out in dimmed room light or within darkened vessels. The cross-linker was used at a 3-fold molar excess over cofactor to maximize linkage via the succinimidyl moiety at neutral pH. Probable sites of apoC-II-(44–79) derivatization included the N terminus and/or basic residues at positions 48, 50, 55, and 76. Excess unbound cross-linker was removed by gel permeation chromatography prior to incubation with LPL.



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FIG. 1.
Strategy to cross-link the cofactor fragment to LPL and to transfer the radiohalide originally on the cofactor to the lipase. A, residues 44–79 of apoC-II were incubated with iodinated SASD in a light-proof environment to form the cofactor·cross-linker complex. B, the isolated complex was incubated with purified LPL and exposed to light and a subsequent reduction step. C, lipase molecules were cleaved by o-iodosobenzoic acid to fragment the protein at tryptophanyl residues, which were resolved by SDS-PAGE, transferred to membranes, and visualized by autoradiography.

 

Step 3—The cofactor·cross-linker complex was incubated with bovine LPL (1 mg/ml) in quartz cuvettes at 4 °C. The samples were irradiated for 3 min by an ultraviolet light source placed 4 cm from the cuvettes, with a mirror positioned 2 cm behind. Some experiments contained a "dark control" sample, which was wrapped in foil during irradiation to determine the effect of the absence of UV light exposure. Other samples contained a 50-fold molar excess of unlabeled cofactor to evaluate cross-linking specificity.

Step 4 —Following UV radiation, samples were treated with dithiothreitol to a final concentration of 10 mM. Reducing agent was used to sever the disulfide bond in the cross-linker moiety (Fig. 1) and served to transfer the iodine label, originally on the cofactor, to a region of LPL at or near the site of interaction. The cofactor provided the binding specificity and, after covalent attachment, was released by dithiothreitol reduction. The label, now attached to the enzyme, was then traced without further involvement of the cofactor. Typical yields of cross-linking reactions ranged from 2 to 5%.

Step 5—Cleavage of LPL was performed with o-iodosobenzoic acid (4 mM). o-Iodosobenzoic acid has been demonstrated to selectively cleave proteins at tryptophan and tyrosine residues under relatively mild conditions (26, 27). Cleavage at tyrosines was eliminated by the inclusion of p-cresol (1 mM), effectively making o-iodosobenzoic acid a tryptophan-specific reagent. SDS-16% polyacrylamide gels were used to separate peptide fragments (nine expected LPL fragments from 8 cleaved tryptophan residues and intact apoC-II (44–79) because it lacks tryptophans). Separated peptides were electrophoretically transferred to polyvinylidene difluoride membranes (Millipore Corp.) for autoradiography and N-terminal sequence analyses.

Construction of ApoC-II Activation Site Chimeras
Six chimeras were created that focused on the proposed apoC-II activation site of LPL (residues 65–68 and 73–79) (Fig. 2). Three of the chimeras had the HL backbone with the suspected regions of LPL replacing the corresponding sections of HL. These enzymes were designated HLLPL-(65–68), HLLPL-(73–79), and HLLPLD (where "D" is double chimera). Conversely, the remaining three chimeras consisted of an LPL backbone with the proposed regions exchanged with the corresponding sections of HL. These enzymes were designated LPLHL-(77–80), LPLHL-(85–91), and LPLHLD.



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FIG. 2.
Schematic diagram of HL and LPL constructs identifying LPL candidate regions exchanged with HL sequences. Site-directed mutagenesis was applied to exchange candidate regions of LPL (stippled) with corresponding HL sequences. The newly created constructs were designated HLLPL-(65–68), HLLPL-(73–79), and HLLPLD (HL backbone with LPL regions replacing the corresponding HL protein sequences) and LPLHL-(77–80), LPLHL-(85–91), and LPLHLD (LPL backbone with the suspected regions removed and replaced with the corresponding HL protein sequences).

 

Primers and PCR Amplification
To aid in purification of the enzymes, the chimeras and wild-type HL and LPL were constructed with a His6 tag. cDNAs for both wild-type HL and LPL had 6 histidines added to the C-terminal end, and these were used as templates for their respective chimeras. The histidine tag was added to wild-type HL and LPL using primers containing histidine codons. The first PCR consisted of the 5'-histidine primer and a 3'-flanking primer specific for the vector pcDNA3 (5'-HL/His6, CAT CAT CAT CAT CAT CAT TGA GAT TTA ATG AAG ACC CA; 3'-primer/pcDNA3; 5'-LPL/His6, CAT CAT CAT CAT CAT CAT TGA AAC TGG GCG AAT CTA CA; and 3'-primer/pcDNA3). The second PCR contained the 3'-histidine primer and the 5'-flanking primer specific to pcDNA3 (3'-HL/His6, ATG ATG ATG ATG ATG ATG TCT GAT CTT TCG CTT TGA TG; 5'-primer/pcDNA3, AAA TGT CGT AAC AAC TCC GCC; 3'-LPL/His6, ATG ATG ATG ATG ATG ATG GCC TGA CTT CTT ATT CAG AG; and 5'-primer/pcDNA3). The purified products were joined together in a third and final PCR using the flanking primers 5'-primer/pcDNA3 and 3'-primer/pcDNA3 for both HL and LPL. For chimeric construction, restriction endonuclease sites were added to primers defining the 5' and 3' termini of the construct to allow for directional cloning. Mutagenic primers (forward and reverse) were designed to span the corresponding boxed coding regions (Fig. 2) and to overlap with one another so that two PCR products could be combined together to form the final full-length cDNA in a third PCR. The primers used for each portion of the chimeras are shown in Table I.


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TABLE I
Primers used for chimeric construction

 

DNA Transfection and Expression
Full-length cDNAs were purified, digested, and inserted into the pcDNA3 expression vector (Invitrogen) using the HindIII and BamHI restriction endonuclease sites. The DNA sequence was confirmed prior to transfection. Chinese hamster ovary Pro5 cells were maintained in Dulbecco's modified Eagle's medium supplemented with 10% fetal bovine serum and antibiotics (Invitrogen). To mediate the transfection of Chinese hamster ovary cells, coprecipitates of plasmid DNA and CaPO4 were prepared (28). The calcium phosphate/DNA mixture was incubated at room temperature for 30 min before it was added to a 50% confluent Chinese hamster ovary monolayer. Stably transfected cells were selected by growth in the presence of Geneticin (G418 sulfate; 500 µg/ml), and surviving colonies were selected and expanded. Cell clones expressing maximal quantities of lipase were identified by enzyme activity analysis.

After growth to confluency in T-175 flasks, the medium was replaced with Opti-MEM (Invitrogen) supplemented with 10 units/ml heparin. The medium was harvested and replaced every 24 h for an 8-day period. After centrifugation at 3000 x g for 10 min to remove cell debris, protease inhibitor mixture for mammalian cell and tissue extracts (Sigma) was added to a final concentration of 0.02 mM, and the harvested medium was stored at –80 °C.

Purification of Recombinant Lipases
All purification steps were carried out at 4 °C. Thawed wild-type or chimeric HL medium (1 liter) was mixed with NaCl to a final concentration of 0.5 M and applied to an octyl-Sepharose column (2.6 x 25 cm) previously equilibrated with 50 mM Tris-HCl, pH 7.2, containing 0.35 M NaCl. Following a wash with 500 ml of 50 mM Tris-HCl, 0.5 M NaCl, 20% glycerol, and 0.02 mM protease inhibitor, pH 7.2 (Buffer A), the lipase was eluted with 500 ml of 50 mM Tris-HCl, 0.35 M NaCl, 20% glycerol, and 0.02 mM protease inhibitor, pH 7.2 containing 1.2% Igepal CA-630 (Sigma) onto a heparin-Sepharose column (2.6 x 25 cm). This column was washed with 500 ml of Buffer A prior to elution with 250 ml of 50 mM Tris-HCl, pH 7.2, 2 M NaCl, 20% glycerol, and protease inhibitor (0.02 mM), onto a 1 x 10-cm metal affinity column (QIAGEN Inc.). The column was washed with 25 ml of Buffer A before elution with 26 ml of 50 mM Tris-HCl, 0.5 M NaCl, and 250 mM imidazole, pH 7.2. The eluent was collected in eight fractions, the first one being 5 ml and the rest 3 ml. Each fraction was assayed for activity, and the active fractions were concentrated in a Millipore filtration unit (molecular mass cutoff of 100,000 Da) to a final volume of ~1 ml and stored at –80 °C. Wild-type LPL and the LPL chimeras were purified in the same manner with two exceptions. 1) The octyl-Sepharose step was omitted; therefore, the thawed medium was loaded directed onto the heparin-Sepharose column with no NaCl added. 2) Buffer A contained NaCl at 0.75 M, not 0.5 M. The purity of the enzyme preparation was determined by densitometry of silver-stained SDS-polyacrylamide gels.

Enzyme Assays
Trioleinase activity was measured using a triolein emulsion containing radiolabeled triolein as described previously (22). ApoC-II-dependent lipase activity was determined by performing the assay in the presence of an apoC-II fragment spanning residues 44–79. This apoC-II fragment has been shown to have the same activating potential as full-length apoC-II (29). Protein concentration was measured by a colorimetric assay developed by Smith et al. (30) using a Pierce micro-BCA protein assay reagent kit. Kinetic constants were determined using GraphPAD Prism Version 3.02 for Windows.

Silver Staining
Gels were fixed in 100 ml of 30% ethanol and 10% glacial acetic acid for 30 min and then washed twice with 10% ethanol and three times with deionized water for 5 min/wash. The gels were soaked in 50 ml of SilverSNAP stain solution with 1 ml of SilverSNAP enhancer solution (Pierce) for 30 min with gentle shaking. The developer was removed, and the gels were washed with deionized water for 30 s. The gels were transferred to 50 ml of SilverSNAP developer with 1 ml of SilverSNAP enhancer for developing until bands appeared.

Electrophoresis and Immunoblotting
Samples were mixed with 0.5 volume of buffer containing 2% SDS, 0.1 M Tris-HCl, pH 6.8, 50% glycerol, 10% {beta}-mercaptoethanol, and 0.05% bromphenol blue. The mixture was placed in boiling water for 5 min prior to loading onto a 10% acrylamide gel. Gels were electroblotted onto a polyvinylidene difluoride hydrophobic membrane that was pretreated with 100% methanol for 10 s. The membrane was placed on filter paper and air-dried for 15 min. The blot was placed in 15 ml of 1% casein and 0.04% Tween 20 (antibody buffer) containing either a monoclonal antibody specific for human HL (22) or a chicken polyclonal antibody raised against bovine LPL (a kind gift from Dr. O. Ben-Zeev) and incubated for 1 h. The blot was rinsed with PBS and washed for 5 min with fresh PBS, which was then repeated twice. Immunoblotting with the monoclonal or polyclonal antibody was detected with either anti-mouse IgG or anti-chicken IgG conjugated to biotin in 15 ml of antibody buffer for 20 min. After washing, the blot was incubated with streptavidin conjugated to horseradish peroxidase in PBS with 0.1% Triton X-100 for 10 min. The blot was developed with chemiluminescent reagents (Pierce) and exposed to chemiluminescent film (Amersham Biosciences).

LPL Enzyme-linked Immunosorbent Assay
200 µl of anti-LPL antibody 5D2 (a kind gift from Dr. John D. Brunzell) (31) was added to each well of a Costar high binding enzyme immunoassay/radioimmunoassay plate at a dilution of 4 µg/ml as previously described (32). The plate was sealed with a Mylar plate sealer and incubated at 37 °C for 4 h. The plate was washed three times with PBS and 0.05% Tween 20. After the third wash, 300 µl of PBS/Tween 20 was added per well, and the plate was then sealed and left overnight at 4 °C. The buffer was removed from the plate, and standards (purified bovine LPL) diluted to 0.1 µg/µl in 50% glycerol and 10 mM NaH2PO4 at pH 7.5, then 4 µl of this solution diluted in 796 µl of 4.56% bovine serum albumin in PBS to 0.5 ng/µl, controls (heparin challenge plasma), and samples (LPL, LPLHL-(77–80), LPLHL-(85–91), and LPLHLD) were added to the plate in quadruplicates at 200 µl/well. The plate was sealed and incubated overnight at 4 °C. Plates were washed four times with PBS/Tween 20; 200 µ of 5D2 peroxidase solution (100 ml of PBS, 100 µl of Tween 20, and 50 µl of 5D2 peroxidase) was added per well; and the plate was sealed and incubated at room temperature for 4 h. The plate was washed five times with PBS/Tween 20. In a darkened room, 200 µl of substrate (75 ml of citrate buffer, pH 5.0, 30 mg of o-phenylenediamine tablet (Sigma), and 150 µl of 3% hydrogen peroxide) was added per well, and the plate was covered and incubated in the dark at room temperature for 10–20 min (the absorbance of the highest standard was 0.600–0.800). 50 µl of 4 M H2SO4 was added per well to stop color development, and the absorbance at 492 nm was determined.

Molecular Modeling
The model of human LPL was generated using, as a template, the 2.46-Å resolution structure of the human pancreatic lipase·colipase complex inhibited by a C11 alkyl phosphonate (Protein Data Bank code 1LPB [PDB] ) (33), which has 30% homology to human LPL. The model was created using the 3D-JIGSAW algorithm (34) (amino acids 1–434 of the mature LPL sequence were modeled) and viewed/analyzed using Swiss-PdbViewer (35).


    RESULTS
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
Binding of ApoC-II to LPL—Binding of the cofactor·cross-linker complex to LPL was assessed by its ability to stimulate lipase activity. The complex stimulated LPL activity to a similar extent as serum (~7-fold) (data not shown), indicating that the presence of the cross-linker had little effect on lipase function. Furthermore, four of the five possible sites of linkage between apoC-II and the cross-linker (residues 44, 48, 50, and 55) are not found in the region of apoC-II believed to activate LPL (36). Thus, it was concluded that the cofactor·cross-linker complex was suitable to probe the cofactor-binding site of LPL.

LPL was incubated with the cofactor·cross-linker complex and then photolyzed, reduced, cleaved, and displayed on denaturing gels (Fig. 3). This autoradiograph of an SDS-16% acrylamide gel shows a single radiolabeled peptide fragment, which migrated below the 3.5-kDa standard, but above the dye front. Lane 2 shows the pattern of another sample run under identical conditions, except for the inclusion of a 50-fold excess of unlabeled apoC-II, and the reduction step was omitted. In this case (as for dark control samples), a 3.5-kDa band was seen; no band was detected corresponding to the band in lane 1. The band migrating at 3.5 kDa corresponded to the size of the apoC-II·cross-linker complex, whose identity was confirmed by microsequence analyses (data not shown). Thus, the 3.5-kDa band in lane 2 is the unbound cofactor·cross-linker complex; and significantly, inclusion of excess unlabeled apoC-II completely eliminated the lower band (Fig. 3, compare lanes 1 and 2), suggesting specific interaction between apoC-II and this portion of LPL.



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FIG. 3.
Autoradiograph of the radiolabeled cofactor·cross-linker complex incubated with LPL following photolysis, reduction, and cleavage. Reaction products were resolved on a 16% acrylamide and 3% bisacrylamide denaturing gel, transferred to polyvinylidene difluoride membranes, and visualized by x-ray film. The migration positions of molecular mass markers and the dye front are show on the left. Lane 1, labeled band after photolysis, reduction, and cleavage of LPL and the cofactor·cross-linker complex; lane 2, labeled product of a sample identical to that in lane 1, except that a 50-fold excess of unlabeled cofactor was added prior to lipase incubation, and the reduction step was eliminated.

 

The mass of the labeled peptide (Fig. 3, lane 1) was determined to be 2.2 kDa by comparison with the migration positions of proteins with known molecular masses. Based on the locations of the 8 tryptophan residues in bovine LPL, the molecular mass of the labeled LPL peptide most closely corresponds to that of peptide 3, from residues 65 to 86 (Table II). This conclusion was supported by the determination of a valine residue at the N terminus of the labeled peptide (data not shown); only the sequence of peptide 3 begins with a valine residue.


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TABLE II
Sizes of bovine LPL fragments following cleavage at tryptophan residues

 

Construction of ApoC-II Activation Site Chimeras—Upon comparison of residues 65–86 of LPL with the corresponding region in HL, two regions of dissimilarity were identified (Fig. 2). To determine whether these sequences are associated with the ability of LPL to be activated by apoC-II, chimeras were created in which the candidate regions of LPL were exchanged with the corresponding HL sequences. The first set of chimeras, designated the HL chimeras, consisted of the HL backbone with the suspected LPL regions replacing the corresponding HL sequences. These regions were exchanged individually (HLLPL-(65–68) and HLLPL-(73–79)) and together (HLLPLD, where "D" is double chimera). The second set of chimeras, the LPL chimeras, is essentially the opposite of the first set. The LPL chimeras have an LPL backbone with the candidate regions of LPL being replaced with the corresponding HL sequences. Again, this was done individually and together, resulting in enzymes with the designations LPLHL-(77–80), LPLHL-(85–91), and LPLHLD (Fig. 2).

Purification and Immunodetection of Chimeras—Following purification of each enzyme, a concentrated sample was run on a polyacrylamide gel (along with samples taken throughout the purification procedure) and silver-stained to determine the purity of the sample. In the concentrated sample, each HL chimera and wild-type HL showed an intense band at 65 kDa that was not visible in the starting culture medium (data not shown). Similar results were seen for the LPL chimeras and wild-type LPL, with an intense band that was visible at 55 kDa in the concentrated samples (data not shown). Purified samples were determined to be >90% pure by scanning densitometry. There was no discernible difference in molecular mass between the chimeras and their respective parental enzymes.

Western blot analysis of all enzymes resulted in a single band at 65 kDa for the HL chimeras and wild-type HL, and a single band was visible at 55 kDa for the LPL chimeras and wild-type LPL (data not shown). Exchanging the 4- and/or 7-amino acid region in any of the chimeric lipases appears to have no effect on the molecular masses of the chimeras compared with the parental enzymes.

Specific Activity of Chimeras—The specific activity of all eight enzymes was determined in conditioned medium and following purification (Table III). With the exception of an ~8-fold difference between HL and HLLPLD, only modest differences were observed for specific activities among the chimeric enzymes measured in conditioned medium. By contrast, much greater differences were seen following purification. Although the specific activity of HL was 4.10 nmol/min/µg, the specific activity of the HL chimeras appeared to decrease as more amino acids were substituted. HLLPL-(65–68) and HLLPL-(73–79) had specific activities of 0.78 and 0.32 nmol/min/µg, respectively, whereas the specific activity of HLLPLD was 0.08 nmol/min/µg. The purified LPL chimeras followed a similar trend, where LPL specific activity was 5.81 nmol/min/µg, and LPLHL-(77–80) and LPLHL-(85–91) specific activities were 0.41 and 0.01 nmol/min/µg, respectively. The specific activity of LPLHLD was unable to be determined due to low protein concentration. A similar pattern of triglyceride hydrolytic activity for all enzymes was observed using the natural substrate very low density lipoprotein (data not shown). To determine whether the differences in specific activity were due to changes in enzyme catalytic activity or possible instability, we measured enzyme activity in medium over a 24-h time course. Initially, the HL chimeras had ~70% the activity of wild-type HL, but lost activity at a faster rate than wild-type HL, with only 8% activity remaining compared with 70% for wild-type HL (data not shown). This suggests that differences in specific activity following purification may be due to the potential instability of the chimeric HL structure. By contrast, the LPL chimeras had similar initial activities in comparison with wild-type LPL and were more stable than their chimeric HL counterparts, with a minimum of 40% activity remaining after 24 h (data not shown). These results suggest that changes in the catalytic potential of the LPL chimeras, in addition to decreased stability, may have caused the observed reductions in their specific activity. To more accurately determine the specific activity of LPL in the culture medium, an enzyme-linked immunosorbent assay method for LPL was applied (Table III). The specific activity of wild-type LPL was greatest at 35.64 nmol/min/µg. The LPL chimeras has specific activities as follows: LPLHL-(77–80), 7.31 nmol/min/µg; LPLHL-(85–91), 23.68 nmol/min/µg; and LPLHLD, 5.99 nmol/min/µg.


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TABLE III
Specific activity of chimeras

The specific activity of all eight enzymes was calculated from conditioned medium, following protein purification, and by measuring LPL mass as described under "Experimental Procedures." Each sample was measured in triplicate, and the results are reported as the mean ± S.D. ND, not determined.

 

Kinetic Analysis—Due to the decreased stability of the chimeric enzymes, kinetic analyses were performed using conditioned medium. The kinetic data and apparent Km and Vmax values are shown in Fig. 4 and Table IV, respectively. There was very little variation in the apparent Km values for both the parental and chimeric enzymes, with values ranging from 176 to 211 nM (Table IV). The low variability in enzyme affinity for substrate suggested a minor alteration of key structures involved in substrate binding, despite the substitution of residues in close proximity to catalytic residues and loop structures (3841). By contrast, greater variability was observed in the apparent Vmax values. The greatest Vmax value was observed for HL at 14.91 nmol/min/mg, but decreased in the HL chimeras as amino acid substitutions were made. The Vmax values for HLLPL-(65–68) and HLLPL-(73–79) were 6.03 and 13.40 nmol/min/mg, respectively. The HLLPLD chimera was associated with a substantial decrease in Vmax, with a value of 1.81 nmol/min/mg. As with wild-type HL, wild-type LPL had the largest Vmax of the LPL enzymes at 7.92 nmol/min/mg. Differences in the Vmax for the LPL chimeras were relatively modest, with LPLHL-(77–80) at 6.41 nmol/min/mg, LPLHL-(85–91) at 2.70 nmol/min/mg, and LPLHLD at 5.14 nmol/min/mg.



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FIG. 4.
Kinetic analysis of wild-type HL and LPL and their chimeric lipases. Analysis of wild-type and chimeric enzyme kinetics was carried out as described under "Experimental Procedures." A, wild-type HL and the HL chimeras. {diamond}, HL; {square}, HLLPL-(65–68); {triangleup}, HLLPL-(73–79); {circ}, HLLPLD. B, wild-type LPL and the LPL chimeras. {diamond}, LPL; {square}, LPLHL-(77–80); {blacktriangleup}, LPLHL-(85–91); •, LPLHLD. Each sample was measured in duplicate, and the results are reported as the mean.

 

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TABLE IV
Apparent kinetic constants of wild-type HL and LPL and their chimeric lipases

Lipase activity was measured in conditioned medium from wild-type and chimeric enzymes using increasing amounts of synthetic triolein (0-1500 nM) in 0.15 M NaCl and in the presence of apoC-II. Data were analyzed as described under "Experimental Procedures." The data are presented as the mean of duplicate measurements.

 

ApoC-II Activation of Chimeras—To assess the lipolytic activity of the enzymes, lipase assays using synthetic triolein substrate were conducted. Lipase activity was measured under two separate conditions: low salt (0.15 M NaCl) with and without apoC-II (Table V). Although chimeras were lower in specific activity compared with wild-type enzymes, it was still possible to determine an effect by apoC-II. Whereas wild-type HL and HLLPL-(65–68) were not activated by apoC-II, HLLPL-(73–79) demonstrated a modest increase in activity of ~1.7-fold. However, HLLPLD was activated 5-fold in the presence of apoC-II. Under the same conditions, wild-type LPL had an ~11-fold increase in activation in the presence of apoC-II, and LPLHL-(77–80) was activated to nearly the same extent. However, LPLHL-(85–91) was activated only ~6-fold, about half the activation of its parental enzyme. Even more compelling data were obtained from LPLHLD. In the presence of apoC-II, the -fold activation of LPLHLD was reduced by two-thirds compared with wild-type LPL.


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TABLE V
Relative trioleinase activity of wild-type HL and LPL and their chimeric lipases

All enzymes were assayed with synthetic triolein substrate to assess their ability to be activated by apoC-II as described under "Experimental Procedures." Activity was measured under low salt (0.15 M NaCl) conditions with and without apoC-II-(44-79) and is expressed relative to the specific activity of each enzyme under low salt conditions, which was assigned a value of 1.0. The data are presented as the mean ± S.D. of three independent measurements in duplicate.

 

Molecular Modeling—To understand the relationship of the identified residues with the catalytic triad of LPL, a three-dimensional molecular model was created (Fig. 5) based on the known structure of human pancreatic lipase (33). Secondary structure prediction indicated that residues 65–68 and 73–75 (7 of the 11 residues of the apoC-II activation domain) are contained in an {alpha}-helix structure (residues 64–75), whereas residues 76–79 were assigned to a random coil. The helix is equivalent to the {alpha}2-helix in the terminology of pancreatic lipase (37). Tertiary protein modeling places this {alpha}-helical region in close proximity to the catalytic pocket (Ser132, Asp156, and His241) and its associated loop structures such as the lid domain (residues 217–238) and the {beta}5-loop (residues 54–63).



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FIG. 5.
Molecular model of human LPL. Residues 64–79 are displayed in ribbon form, with the {alpha}-helix region (residues 64–75) displayed in red and the random coil (residues 76–79) in blue. The catalytic triad of LPL (Ser132, Asp156, and His241) is space-filled and highlighted in green, whereas the sequence of loops appears in purple (residues 54–63) and red (residues 217–238). The backbone of the remaining residues terminating at position 434 is yellow.

 


    DISCUSSION
 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
 REFERENCES
 
ApoC-II has been recognized as the principal activator of LPL for some time (17, 18), but the mechanism by which this activation takes place remains poorly understood. To gain further insight into this mechanism, we utilized cofactor cross-linking and the domain exchange approach to determine residues in the N-terminal domain of LPL that are responsible for the ability to be activated by apoC-II.

Our previous studies utilizing chimeric lipases placed one of the LPL apoC-II-binding sites within the first 312 amino acids (the N-terminal domain) (20, 38) and a second site in the last half of the C-terminal domain (residues 389–448) (22). From the expected sizes of LPL fragments generated by o-iodosobenzoic acid cleavage (Table III), it is clear that the second half of the N-terminal domain and the first half of the C-terminal domain are contained in peptide 5, with a molecular mass of ~30 kDa. Labeling was not seen in that sized fragment, thereby excluding those regions in cofactor interaction. The labeled peptide observed in Fig. 1 has a molecular mass consistent with that of peptide 3 (residues 65–86). The identity of the labeled peptide as residues 65–86 was confirmed by sequencing analysis, which identified an N-terminal valine residue; and only peptide 3 begins with that amino acid. Additional labeled peptides were not detected, but other sites of cofactor interaction cannot be ruled out. In fact, it is expected that apoC-II does interact with elements of the C-terminal domain based on previous studies on chimeras (22); but for technical reasons, these peptides may not have been resolved under the current experimental conditions. For example, peptides 6–8 are too small to distinguish from the dye front; thus, it cannot be excluded that apoC-II also interacts with these regions of the molecule. Peptide 3 (residues 65–86) occupies a highly conserved region of LPL (3). Its amino acid sequence is identical in six species, except for a single substitution of aspartate for alanine in chicken LPL. More importantly, comparison of this region between LPL and the highly related enzyme HL revealed significant differences. Because HL activity is not stimulated by apoC-II, the longest contiguous stretch of amino acids in this region of the molecule that differed between the two enzymes suggested specific candidate residues participating in LPL-cofactor interaction. A 4-amino acid (LPL residues 65–68) and 7-amino acid (LPL residues 73–79) region of dissimilarity in sequence homology was identified, and a series of HL and LPL chimeras were constructed in which these regions were exchanged either alone (HLLPL-(65–68), HLLPL-(73–79), LPLHL-(77–80), and LPLHL-(85–91)) or together (HLLPLD and LPLHLD). The first set of chimeras consisted of an HL backbone with the LPL candidate segments replacing the corresponding HL sequences, whereas the second set of chimeras consisted of an LPL backbone with the LPL candidate segments replaced with HL sequences.

Comparison of the specific activity measurements of the enzymes indicated that the substitution of analogous residues into either lipase resulted in decreased activities (Table III). The lowest activity among the LPL chimeras was associated with the simultaneous substitution of both LPL candidate amino acid regions (~6-fold difference compared with wild-type LPL). A similar result was observed for the HL chimeras. This effect was amplified following purification as result of an inherent decreased stability associated with the chimeric enzymes, particularly apparent in the HL chimeras. Despite the reduced specific activities of the chimeras following purification, it was reasoned that apoC-II responsiveness of the remaining active species could be an accurate measure of the part played by the substituted residues. Kinetic analyses of these lipases (Table IV) indicated very little change in Km, consistent with previous findings indicating that the primary effect of apoC-II is on the Vmax of the reaction (39). The greatest difference in Vmax values was observed between wild-type HL and HLLPLD (~8-fold), suggesting that the presence of LPL residues in this chimera impaired catalysis compared with wild-type HL. However, the presence of both LPL candidate regions in HL resulted in a reduction in lipolysis, which was not due to altered affinity of the enzyme for the substrate, but to other factors such as stability and the inability to bind substrate productively. Significantly, the level of remaining activity was stimulated 5-fold by apoC-II, the first report of the transference to HL of LPL cofactor-dependent lipolysis.

Measurement of the enzyme activity of the chimeras in the presence and absence of apoC-II indicated that LPL residues 65–68 alone were not able to confer apoC-II reactivity to HL (Table V). Similarly, the exchange of these same residues for corresponding HL residues in LPL did not appreciably change the -fold activation in comparison with wild-type LPL (~10-fold versus ~11-fold). By contrast, there was an indication that LPL residues 73–79 were involved in apoC-II activation, as the presence of this second sequence in HL was associated with a modest increase in activity in comparison with wild-type HL. More convincingly, there was only an ~6-fold activation when these residues were replaced in LPL, a reduction of nearly half the activation observed for the native enzyme. However, it was only when both LPL regions (residues 65–68 and 73–79) were replaced that the largest effects on activation were seen. Chimeras with both regions exchanged were associated with an ~5-fold activation in the case of the HL chimera and with a 67% reduction in activation for the LPL chimera. These results suggest that LPL amino acids 65–68 and 73–79 act cooperatively in response to activation by apoC-II. It is important to note, however, that the LPL chimera with both candidate regions replaced did not completely abolish activation by apoC-II; and when inserting these regions into HL, we did not obtain maximal activation compared with wild-type LPL. These findings indicate that, although LPL amino acids 65–68 and 73–79 are indeed necessary, they are not sufficient for the complete activation of LPL by apoC-II. This finding is consistent with our previous study indicating that, in addition to a region in the N-terminal domain, an apoC-II-responsive region also exists in the C-terminal domain of LPL (22).

Evidence has been provided that apoC-II and LPL participate in a protein-protein interaction that involves two molecules of apoC-II for each LPL dimer (40). The portion of apoC-II thought to activate LPL hydrolysis was initially localized to the C-terminal third of the sequence (41). Furthermore, apoC-II peptide inhibition studies have identified the 4 terminal amino acids (residues 76–79) as important for the initial binding of apoC-II to LPL, but not directly for activation (42). More specifically, site-directed mutagenesis studies have implicated Tyr63 in apoC-II as a key residue in the activation mechanism, but no single amino acid appears to be essential for activation (43, 44). NMR structural studies of apoC-II have described a number of helical domains thought to associate with lipid (36, 45). Two of these domains in apoC-II (residues 50–58 and 66–75) are located in the C-terminal region, and the latter has been suggested to represent one of the major lipid-binding domains (36). It has been suggested that this helix, together with a helix located in the N-terminal domain (14), may anchor apoC-II to the lipoprotein surface, whereas the interhelical region formed by residues 59–65 may represent the primary activator domain of apoC-II (36).

The LPL model presented in this study (Fig. 5) indicates that residues 65–68 and 73–79 are found in close proximity to the catalytic pocket (Ser132, Asp156, and His241) and both loop domains (residues 54–63 and 217–238). In addition, secondary structure prediction indicates that residues 64–75 constitute an {alpha}-helical domain that may enable this region to interact with lipid moieties. However, because models of HL also predict {alpha}-helix structure in this region,2 secondary structure alone cannot explain apoC-II activation. Consequently, helical wheel diagrams of this region for LPL and HL were compared (Fig. 6), and differences in the number of charged residues and amphipathicity are readily apparent. The specified LPL region contains Lys67, Lys74, Arg75, Glu76, and Asp78, whereas the corresponding HL region contains only a single Lys at position 85. The charged and hydrophobic residues in an LPL helix are arranged in a highly amphipathic manner, whereas the corresponding HL region lacks that character. As a result, we suggest that electrostatic interactions may contribute to the interaction of apoC-II with LPL, permitting substrate access to the active site. We speculate that, in LPL, this helix (residues 64–75) either directly or indirectly prevents substrate access to the active site in the absence of apoC-II. Furthermore, because HL has obvious compositional differences at this site, this helix in HL may not normally interfere with substrate access, thus obviating the need for cofactor. In summary, we have shown that LPL residues 65–68 and 73–79 appear to act cooperatively to enable substantial activation of human LPL by apoC-II and, moreover, that the responsiveness imparted by these LPL residues can be translocated to HL. These findings suggest these LPL residues are (or are part of) the N-terminal domain cofactor activation site of the enzyme.



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FIG. 6.
Helical wheel diagrams of LPL and HL. Residues 65–79 of LPL (A) and residues 77–91 of HL (B) are displayed in helical wheel form. Charged residues are indicated in red, hydrophobic residues in green, and hydrophilic residues in yellow.

 


    FOOTNOTES
 
* This work was supported in part by the Heart and Stroke Foundation of British Columbia and Yukon. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. Back

§ Supported by a research traineeship from the Heart and Stroke Foundation of British Columbia and Yukon. Back

** Supported by the Veterans Affairs Merit Review and National Institutes of Health Grant HL28481. Back

{ddagger}{ddagger} Scholar of the Heart and Stroke Foundation of Canada and the Michael Smith Foundation for Heath Research. To whom correspondence should be addressed: St. Paul's Hospital, Healthy Heart Program, 1081 Burrard St., Vancouver, BC V6Z 1Y6, Canada. Tel.: 604-806-8616; Fax: 604-806-8590; E-mail: jshill{at}interchange.ubc.ca.

1 The abbreviations used are: HL, hepatic lipase; LPL, lipoprotein lipase; SASD, sulfosuccinimidyl-2-(p-azidosalicylamido)ethyl 1,3'-dithiopropionate; PBS, phosphate-buffered saline. Back

2 J. S. Hill, unpublished data. Back


    ACKNOWLEDGMENTS
 
We gratefully acknowledge the laboratory of Dr. John D. Brunzell for providing anti-LPL antibodies and technical support in the development of the LPL enzyme-linked immunosorbent assay and Dr. Pak Poon for critical reading of the manuscript.



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 TOP
 ABSTRACT
 INTRODUCTION
 EXPERIMENTAL PROCEDURES
 RESULTS
 DISCUSSION
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