Tài liệu Báo cáo Y học: Molecular modeling of the dimeric structure of human lipoprotein lipase and functional studies of the carboxyl-terminal domain docx

Keywords: lipoprotein lipase; dimeric model structure; heparin binding; substrate recognition; catalytic activity.. Construction of the LPL model structure The LPL model structure was co

Molecular modeling of the dimeric structure of human lipoprotein lipase and functional studies of the carboxyl-terminal domain

Yoko Kobayashi, Toshiaki Nakajima and Ituro Inoue

Division of Genetic Diagnosis, Institute of Medical Science, The University of Tokyo, Tokyo, Japan

Lipoprotein lipase (LPL) plays a key role in lipid

metabo-lism Molecular modeling of dimeric LPL was carried out

usingINSIGHT IIbased upon the crystal structures of human,

porcine, and horse pancreatic lipase The dimeric model

reveals a saddle-shaped structure and the key

heparin-binding residues in the amino-terminal domain located on

the top of this saddle The models of two dimeric

conformations – a closed, inactive form and an open, active

form – differ with respect to how surface-loop positions

affect substrate access to the catalytic site In the closed form,

the surface loop covers the catalytic site, which becomes

inaccessible to solvent Large conformational changes in the

open form, especially in the loop and carboxyl-terminal

domain, allow substrate access to the active site To dissect

the structure–function relationships of the LPL

carboxyl-terminal domain, several residues predicted by the model

structure to be essential for the functions of heparin binding

and substrate recognition were mutagenized Arg405 plays

an important role in heparin binding in the active dimer Lys413/Lys414 or Lys414 regulates heparin affinity in both monomeric and dimeric forms To evaluate the prediction that LPL forms a homodimer in a
head-to-tail orientation, two inactive LPL mutants – a catalytic site mutant (S132T) and a substrate-recognition mutant (W390A/W393A/ W394A) – were cotransfected into COS7 cells Lipase activity could be recovered only when heterodimerization occurred in a head-to-tail orientation After cotransfection, 50% of the wild-type lipase activity was recovered, indica-ting that lipase activity is determined by the interaction between the catalytic site on one subunit and the substrate-recognition site on the other

Keywords: lipoprotein lipase; dimeric model structure; heparin binding; substrate recognition; catalytic activity

Lipoprotein lipase (LPL) belongs to a mammalian lipase

family that includes pancreatic lipase (PL), hepatic lipase

(HL), gastric lipase, and endothelial lipase [1,2] The

primary function of LPL is triglyceride hydrolysis in

triglyceride-rich lipoproteins, such as chylomicron and very

low density lipoprotein (VLDL) particles, which are

converted to remnants LPL is secreted from a variety of

tissues, such as adipocyte, macrophage, and muscle cells,

and is bound to the capillary bed of endothelium via cellular

surface heparan sulfate proteoglycans (HSPG), a function

reflected in LPL’s strong affinity for heparin LPL

defici-encies in humans are manifested as severe

hypertriglyceri-demia [3–5] and arteriosclerosis [6] Genetically engineered

mice lacking LPL also exhibit hypertriglyceridemia In

addition to lipolytic activity, LPL functions as a ligand for

lipoprotein receptors, such as low density lipoprotein (LDL)

receptor, LDL receptor related protein (LRP), GP330/

LRP-2, and VLDL receptor [7–11]

A model structure of LPL had previously been construc-ted, based on the crystal structure of human PL as a template [12] The model structure exhibited two domains –

a large N-terminal domain (1–312 amino acid residues) and

a small C-terminal domain (313–448 residues) The sequences of PL and LPL are identical at 31% of their residues in the N-terminal domain (40% similarity) and are 28% identical in the C-terminal domain (38% similarity) The catalytic efficiency and heparin-binding functions of the N-terminal domain have been extensively studied [13,14] A chimeric enzyme with the N-terminal domain of LPL and the C-terminal domain of HL (LPL/HL) exhibited the characteristic catalytic activity of LPL, as well as other LPL-specific functions, such as activation by ApoC-II and inhibition by NaCl [15] Horse PL [16], human PL [17], and complexes of human PL and procolipase [18,19] have been crystallized These studies demonstrated that the active site in the N-terminal domain has two conformations – an active, open conformation and an inactive, closed confor-mation [18] A surface loop functions as a lid and governs the interaction of the lipid substrate with the enzyme’s catalytic site [20] On the protein surface at a site opposite to the lid, occurs a cluster of basic amino acids (Arg279, Lys280, Arg282) that constitutes a high-affinity, heparin-binding site [14]

The function of the C-terminal domain has also been addressed with a chimeric enzyme (LPL/HL), which exhibits an affinity for heparin similar to that of native LPL [21], suggesting that the major heparin-binding site occurs in LPL’s N-terminal domain Recently, however, several lines of evidence have demonstrated that the

Correspondence to I Inoue, Division of Genetic Diagnosis, Institute

of Medical Science, The University of Tokyo, Shirokanedai 4-6-1,

Minato-ku, Tokyo 108-8639, Japan.

Fax: + 81 3 5449 5764, Tel.: + 81 3 5449 5325,

E-mail: ituro@ims.u-tokyo.ac.jp

Abbreviations: LPL, lipoprotein lipase; PL, pancreatic lipase;

HL, hepatic lipase; VLDL, very low density lipoprotein; HSPG,

heparan sulfate proteoglycans; LDL, low density lipoprotein; LRP,

LDL receptor related protein; DMEM, Dulbecco’s modified Eagle’s

medium; ADIFAB, acrylodated intestinal fatty acid binding protein.

(Received 17 May 2002, revised 26 July 2002, accepted 13 August 2002)

C-terminal domain is also important in heparin binding.

The Arg405, Arg407, and Lys409 residues of avian LPL,

which correspond to the Lys403, Arg405, and Lys407

residues, respectively, in the C-terminal domain of human

LPL, have been demonstrated to be responsible for

heparin binding [22] In another study with transgenic

mice expressing a human LPL with Asn residues

substi-tuted for basic amino acids at positions 403, 405, and 407,

the mutant LPL displayed normal enzyme activity but

with a reduced affinity for heparin [23] The investigators

of the latter study concluded that HSPG binding at the

cell surface is required for maintaining LPL stability

LPL’s C-terminal domain also appears to be involved in

the binding of the enzyme to receptors such as the LDL

receptor related protein (LRP) [24,25], with the critical

LRP-binding site having been demonstrated to be between

residues 340 and 438 Positively charged amino acid

residues in this region were replaced with Ala to test

receptor binding, because LPL is expected to interact with

the negative charges in LRP’s cysteine-rich repeats [26]

Thus, Lys407 was shown to be important for LRP

binding, whereas substitutions for Lys413 and/or Lys414

and Arg405 demonstrated only weakly decreased affinities

for LRP [24] The C-terminal domain also has an

important function in binding lipid substrate A cluster

of tryptophans – Trp390, Trp393, and Trp394 – which the

model structure revealed to be on the protein surface,

play a role in orienting the enzyme at the lipid–water

interface [27]

To better understand LPL’s dimeric structure and its

related functions, we constructed a model structure of the

dimeric form of LPL by using the crystal structures of

human, porcine, and horse PL as templates in which the

subunits are in a
head-to-tail orientation Two dimeric LPL

model structures were constructed and were based on the

two PL forms in the protein database – the open form with

bound procolipase and the closed form without it Amino

acid substitutions in the C-terminal domain were made to

address the functional roles of the C-terminal domain in

heparin binding and in catalytic activity We also provide

experimental evidence of head-to-tail subunit orientation by

producing a functional heterodimer from two distinct and

inactive mutant subunits

M E T H O D S

Site-directed mutagenesis and expression of LPL

in cultured cells

A cDNA fragment containing the entire coding region of

human LPL was subcloned into expression vector pMT2 at

the EcoR1 site [14] Nucleotide substitutions were generated

by the Chameleon double-stranded, site-directed

mutagene-sis kit (Stratagene, La Jolla, CA, USA) All the constructs

were verified by direct sequencing

COS7 cells were maintained at 37C and 5% CO2

atmosphere in Dulbecco’s modified Eagle’s medium

(DMEM), supplemented with 10% fetal bovine serum,

100 UÆmL)1of penicillin, 100 lgÆmL)1of streptomycin, and

0.25 lgÆmL)1 of amphotericin B Cells (1.8· 106) were

plated onto a 10-cm dish 1 day before transfection The

pMT2 vector containing either wild-type or mutant LPL

was transfected with the LipofectAMINETM reagent

(Invitrogen Japan K.K., Tokyo, Japan) according to the manufacturer’s protocol Two days after transfection, the cells were washed twice with DMEM without phenol red To release LPL from the cell surface, the cells were treated with 20 UÆmL)1of heparin (Sigma Aldrich Japan K.K., Tokyo, Japan) at 37C for 8 h, and then the conditioned media were collected

In vitro translation of the LPL C-terminal domain

A cDNA segment corresponding to the C-terminal domain

of LPL was placed under the control of the T7 promoter in the pET4 vector (Novagen Inc., Madison, WI, USA)

In vitrotranscription/translation reactions were performed with TNT T7 quick-coupled transcription/translation sys-tem in rabbit reticulocyte lysate (Promega Co., Madison,

WI, USA) labeled with [35S]-methionine (Amersham Bio-sciences K.K., Tokyo, Japan)

Determination of LPL heparin affinity The heparin affinities of whole-molecule LPL or the C-terminal domain alone were determined by running a heparin FPLC system as previously described [14] The proteins were separated by heparin-Superose chromatogra-phy and eluted by a 0–1.5M linear NaCl gradient NaCl concentration was directly monitored by flame spectropho-tometry [14]

LPL concentration determination LPL concentration was determined with a MARKIT-F LPL kit (Dai-Nippon Pharmaceutical Co., Osaka, Japan), which is based on the sandwich-ELISA developed for human LPL The kit contains two kinds of LPL monoclo-nal antibody against human LPL purified from postheparin plasma One of the monoclonal antibodies, has an epitope similar to that of the 5D2 monoclonal antibody and was conjugated with b-D-galactosidase, and the other was coupled with insoluble bacterial cell walls LPL concentra-tion was measured as the catalytic activity with 4-methyl-umbelliferyl b-D-galactoside as a substrate Fluorescence emission signals at 450 nm after excitation at 365 nm were monitored with a spectrofluorometer FP750 (JASCO Co., Tokyo, Japan)

Assay of lipase and esterase activities Acrylodated intestinal fatty acid binding protein (ADI FAB; FFA science LLC, San Diego, CA, USA) was used

to determine lipase activity [28] The lipase substrate was a mixture of triolein and phosphatidylcholine at a weight ratio of four to one [29] The lipid mixtures were dissolved

in chloroform and dried under nitrogen gas The triolein/ phosphatidylcholine mixture was emulsified by sonication

in 20 mM Hepes, 150 mM NaCl, 5 mM KCl, 1 mM

Na2HPO4, pH7.4 The enzyme was incubated in the same buffer with 10 nmolÆmL)1 triolein at 37C for

30 min Adding NaCl to a final concentration of 1M

stopped the reaction ADIFAB responds to fatty-acid binding by shifting its fluorescence emission from 432 nm

to 505 nm [28] The product of the lipase reaction, free fatty acid, was measured after the addition of ADIFAB to

final 0.2 lM, and the ratio of the fluorescence intensity at

505 nm to that at 432 nm was determined at an excitation

wavelength of 386 nm Oleic acid was used as a standard

for free fatty acid

Esterase activity was measured using p-nitrophenyl

butyrate as a substrate Samples were incubated at 37C

for 20–40 min in 150 mM NaCl, 0.5% Triton X-100,

100 mM sodium phosphate buffer (pH7.0), and 500 lM

p-nitrophenyl butyrate Absorbance of the product,

p-nitrophenol, was measured at 400 nm with a DU640

spectrophotometer (Beckman Coulter Inc., Los Angeles,

CA, USA)

Western blotting

Proteins in the conditioned media were separated by

electrophoresis on a 12.5% polyacrylamide gel, followed by

electrotransfer onto a poly(vinylidene difluoride) membrane

(Nihon Millipore Ltd., Tokyo, Japan) The membranes were

blocked to prevent the binding of nonspecific proteins with

Block Ace (Dai-Nippon pharmaceutical) Anti-LPL

mono-clonal antibody 5D2 (Calbiochem-Novabiochem Co., San

Diego, CA, USA), anti-(bovine LPL) polyclonal lg (Ab7640)

provided by P.-H Iverius (University of Utah, Salt Lake

City, UT, USA), or anti-(His-tag) polyclonal Ig (Medical

and Biological Laboratories Co., Nagoya, Japan) was used

to detect LPL or His-tagged proteins Bound antibody was

reacted with HRP conjugated anti-rabbit or anti-mouse IgG

and developed with enhanced chemiluminescence reagents

(Amersham Biosciences K.K., Tokyo, Japan) on an

LAS-1000 plus image analyzer (Fuji Film, Tokyo, Japan)

Construction of the LPL model structure

The LPL model structure was constructed using the

molecular modeling systemINSIGHT IIversion 2000 (Accelrys

Inc., Burlington, MA, USA) on a Silicon Graphics

workstation and was based on the structures of the human

and porcine pancreatic lipases for the open form and on

the horse pancreatic lipase for the closed form [16,18,19,30]

For homology modeling, the 11 C-terminal residues of

LPL were removed from the model because no

homolo-gous region occurred in PL The crystal structures of

human and porcine PL (Protein Data Bank accession

numbers 1LPA and 1ETH) obtained from the protein

structure database (http://www.rcsb.org/pdb/) include

bound procolipase, and these structures represent the

active form (open form) of the enzyme Because no

sequence homology between procolipase and ApoC-II

was observed, procolipase was dissociated from the

struc-ture to model the open form of LPL The crystal strucstruc-ture

of horse PL (Protein Data Bank accession number 1HPL)

exhibited a dimeric structure in its inactive form in which a

surface loop concealed the active site from the solvent

After the homology modeling, addition of hydrogen,

modification of bonds, potentials of forcefield, and fixation

of heavy atom, backbone, and Ca, were performed for

molecular mechanics calculations and then the energy

minimization of the model was iterated 300 cycles using the

conjugate gradient methods with the programDISCOVER_3

inINSIGHT II To construct the dimeric form of LPL, the

model structure of monomeric LPL was duplicated and

superimposed on the crystal structure of the horse PL

dimer After the energy minimization by setting at iteration

of 300 cycles or energy level of the final convergence at 0.002 kcalÆmol)1ÆA˚)1was achieved using conjugate gradi-ent method after fixation of heavy atom, backbone, and

Ca, the dimeric structure of LPL was finalized The averaged distance between Ser132 and Trp393 was calcu-lated using the viewer module inINSIGHT II In addition, a mutation model of LPL was constructed after substituting Ala for each basic amino acid, after performing the energy minimization at final convergence at 0.002 kcalÆmol)1ÆA˚)1or

by iteration of 300 cycles The substitution model structures were then used for the molecular dynamics simulations The velocity verlet method implemented in theDISCOVER_3 module ofINSIGHT IIwas used at a constant temperature of 298.0 K for 5000 steps of 1.0 fs time-step

R E S U L T S

Model structure of human LPL All model structures of dimeric human LPL were construc-ted using the INSIGHT II program and were based on the crystal structures of the human, porcine, and horse PLs (Fig 1) A frontal view illustrates the overall saddle shape of the dimeric structure and the key heparin-binding residues

in the N-terminal domain held coordinately by the two subunits on the top of the hollow (Fig 1A) The model structure of the C-terminal domain illustrates two features One is a lining-up of basic residues (Arg405, Lys407, Lys413, Lys414, Lys422, Lys428, and Lys430) oriented in the same direction with the heparin-binding domain at the N-terminal end [14] The other is a cluster of tryptophans (Trp390, Trp393, and Trp394) exposed to the surface (Fig 1A) The cluster of basic residues in the C-terminal domain may constitute heparin binding-site residues that coordinate with heparin-binding residues in the N-terminal domain The cluster of hydrophobic residues may function

in substrate recognition, as has been reported previously [27]

LPL forms a homodimer and the dimer is conceivably in

a head-to-tail orientation As has been demonstrated with

PL, the LPL model contains a surface loop covering the catalytic pocket that modulates substrate access to the active site Two dimeric conformations – a closed, inactive form and an open, active form – were modeled so that the surface-loop positions differ (Fig 1B) The figure of the closed form illustrates that the surface loop covers the catalytic site, which makes it inaccessible to solvent This observation suggests that substantial conformational chan-ges must take place before substrate can bind to the active site The active LPL structure (open form) was modeled from the structures of human and porcine PL cocrystallized with procolipase, for which drastic conformational changes, especially in the loop and the C-terminal domain, are necessary to allow substrate access to the active site (Fig 1B) The loops of both peptides form regular helix-turn-helix structures and lie close to each other, and a substantial conformational change in the C-terminal domain is induced The key heparin-binding site of basic amino acids in both peptides is located at a site opposite to that of the active center, suggesting that heparin binding regions may not play a direct role in LPL catalytic activity (Fig 1B)

Fig 1 Molecular modeling of the dimeric structure of LPL Two dimeric model structures of LPL were constructed using INSIGHT II version 2000 on

a Silicon Graphics workstation The model structure of the closed form was generated from horse pancreatic lipase as a template (left), whereas the model structure of the open form was from human and porcine pancreatic lipase (right) The structural views are from the side (A) or the top (B) The N-terminal heparin-binding site (residues 279–282) is in yellow, the basic amino acids in the C-terminal domain are in green, and the cluster of hydrophobic residues Trp390, Trp393, and Trp394 is in red The catalytic site is enlarged in B and illustrates the conserved disulfide bridge between Cys239 and Cys216 (black) and two distinct structures of the lid (orange).

Heparin affinity ofin vitro translated C-terminal

domain of LPL

Because C-terminal truncated proteins purified from a

prokaryotic system were eluted from the heparin affinity

column at extremely low efficiency, the proteins produced in

the in vitro system were measured for heparin affinity

(Table 1) The C-terminal domain of wild-type LPL (amino

acid residues 313–448) or its mutants, K381A, R405A,

K407A, K413A/K414A, K422A, K428A, and K430A, was

applied to a heparin-Superose FPLC system and eluted by a

linear NaCl gradient The wild-type C-terminal domain was eluted at 0.48 M NaCl, whereas the substituted mutants, R405A and K407A, demonstrated reduced affinities for heparin by eluting at 0.33Mand 0.39MNaCl, respectively The K413A/K414A mutant demonstrated a low affinity for heparin by eluting at 0.26MNaCl Other mutants (K381A, K422A, K428A, and K430A) did not exhibit any altered affinity for heparin by this method

Impact of C-terminal substitutions on heparin binding to full-length LPL

The affinities of heparin for full-length LPLs after muta-genesis of residues in the C-terminal domain were examined (Fig 2) by heparin-affinity chromatography of the condi-tioned media collected from cells transfected with either wild-type or substitution mutant LPL Chromatography yielded two distinct immunoreactive peaks with a linear NaCl gradient The high-affinity peak corresponds to active LPL homodimer, whereas the low-affinity peak corresponds

to inactive monomer together with some intermediate degradation products In the K413A/K414A mutant, the two LPL peaks both eluted at lower salt concentrations than those of wild-type LPL The R405A mutant exhibited

an earlier elution of the high-affinity peak, whereas the elution of the low-affinity peak was unchanged

To investigate the effect of substitutions in the tryptophan cluster of the C-terminal domain on heparin affinity, the W393A/W394A (WW) mutant was applied to the heparin FPLC column (Fig 3A) Because the epitope recognized by the monoclonal antibody in the MARKIT-F LPL kit is near the peptide sequence containing Trp393 and Trp394

Table 1 Heparin affinity of C-terminal domain of LPL.

In vitro product of

C-terminal domain

Heparin affinity NaCl ( M )

Fig 3 Heparin binding of wild-type LPL and the WW mutant Wild-type LPL (left) and WW mutant (right) were applied to heparin-Superose FPLC and eluted by a linear NaCl gradient (A) LPL concentration (j), lipase activity (h) The concentrations of the WW mutant could not be detected with the MARKIT-F LPL kit, and chromatography fractions were analyzed by Western blotting with LPL polyclonal antibody 7640 (B).

Fig 2 Heparin affinity of wild-type and basic amino acid–substituted

LPL Proteins, released from LPL or LPL mutant–expressed COS7

cells, were subjected to heparin-Superose FPLC as described in [14].

Bound LPL was eluted by a linear NaCl gradient (broken line), and

concentrations of LPL (j) and lipase activities (h) were measured in

each fraction as described in the Materials and methods The upper,

middle, and lower panels are the wild-type LPL, the K413A/K414A

mutant, and the R405A mutant, respectively.

(information from supplier), where the epitope of

monoclo-nal antibody 5D2 exists [27], no detectable LPL

concentra-tion was recovered for the WW mutant Only a trace peak of

LPL activity was detected at the same position as the

high-affinity peak of wild-type LPL The LPL in the eluate was

detected by Western blot with LPL polyclonal antibody

7640 The fraction number of the high-affinity peak was the

same for the wild type and the WW mutant (Fig 3B)

Catalytic activities with long- and short-chain

fatty acid substrates

To study the functional impact of the LPL C-terminal

domain on catalytic activity, wild-type and mutant proteins

R405A, K413A, K413A/K414A, K414A, and S132T were

obtained from the conditioned media of transfected COS7

cells (Fig 4A,B) Lipase activity was measured with a

long-chain fatty acid, triolein, as a substrate The K413A mutant

exhibited the same level of lipase activity as wild type The

lipase activities of the other mutants, R405A, K413A/

K414A, and K414A, were lower Esterase activity measured

with the short-chain fatty acid substrate, p-nitrophenyl

butyrate, indicated that the esterase activities of the R405A and K413A mutants were reduced to about half those of the wild type, whereas the K413A/K414A and K414A mutants, like the S132T mutant, lost esterase activity

Next, the effects of the surface tryptophan substitutions at the C-terminal domain on the lipase and esterase activities were examined (Fig 4C,D) Because the LPL concentration

of the mutants, WW and W390A/W393A/W394A (WWW), could not be determined with the MARKIT-F LPL kit, their lipase and esterase activities are not expressed as specific activities To confirm the LPL levels in the assay, Western blot with anti-(His-tag) Ig was carried out in order to detect the His-tagged LPL Lipase activity was not detected in WW

or WWW mutants, whereas both mutants catalyzed the short-chain fatty acid at the same rate as wild-type LPL Addition of the His-tag to the LPL C-terminus did not affect enzyme activities (shown in Fig 6B)

Conformational changes in the LPL mutant models The model structures of R405A, K413A, and K414A mutants were performed using the molecular dynamic

Fig 4 Lipase and esterase activities of amino acid–substituted mutants The catalytic acti-vities were measured as described in the Materials and methods LPL, released from transfected COS7 cells by adding heparin to the media, was assayed for catalytic activity The lipase (A) and esterase (B) activities of the substituted mutants, R405A, K413A, K413A/ K414A, K414A, and S132T, are presented as specific activities Catalytic activities for the

WW mutant (Ala substituted for Trp393 and Trp394) and the WWW mutant (Ala substi-tuted for Trp390, Trp393 and Trp394) (C,D) Protein expression of the wild type, the WW mutant, and the WWW mutant tagged with polyhistidine were evaluated by Western blotting with (His-tag) polyclonal anti-body (insert in D).

simulation after substitution of the residues, and the LPL

mutant models were superimposed on wild-type LPL

(Fig 5) The K413A mutant retains normal lipase and

esterase activities, and the structure of the K413A mutant

is similar to that of wild-type LPL The model of the

R405A mutant, which has low lipase activity and a normal

esterase activity, displays a substantial conformational

change in the substrate-binding site in the C-terminal

domain (red arrow) Modeling of the K414A mutant,

which exhibits decreased lipase and esterase activities,

reveals substantial conformational changes in the

N-ter-minal heparin-binding site (blue arrow) and the substrate

recognition site (red arrow)

Recovery of lipase activity after cotransfection

of S132T and WWW mutants

Two possible subunit orientations have been postulated for

LPL, head-to-head and head-to-tail The crystal structure of

PL suggests that a head-to-tail dimeric structure is the most

likely, but experimental evidence in support of this

hypo-thesis are meager In the head-to-tail orientation, the

catalytic site in the N-terminal domain of one subunit and

the substrate recognition site in the C-terminal domain of

the other face each other, thereby bringing together the

substrate-binding and catalytic functions in proximity for

effective enzyme activity

Two LPL mutants lacking the lipase activity – one a catalytic site mutant (S132T) and the other a substrate recognition site mutant (WWW) – were cotransfected into COS7 cells (Fig 6) If the head-to-tail model is correct, then 50% of the normal LPL activity should be recovered stoichiometrically after the cotransfection experiment (Fig 6A) If head-to-head dimerization occurs, no lipase activity is expected Lipase and esterase activities (Fig 6B) are expressed per mL because the concentration of the LPL WWW mutant could not be quantified The lipase activity

of the His-tagged, wild-type LPL was comparable to that of wild-type LPL WWW and His-tagged WWW mutants both exhibited only a trace amount of lipase activity, similar

to that of the S132T mutant, but both retained the esterase activity After the cotransfection of S132T and His-tagged WWW mutants, almost half of the lipase activity was recovered, indicating a head-to-tail subunit orientation (Fig 6B) A similar result was obtained for the esterase activity A Western blot confirmed that the two mutant proteins were expressed in equivalent amounts (Fig 6C)

D I S C U S S I O N

LPL exerts its biological role at a lipid/water interface Consequently, its catalytic function requires a unique structure that exposes the lipid-binding site In the absence

of a crystal structure for LPL, any investigation into LPL

Fig 5 Model structure of basic amino acid–substituted mutants The mutant models after Ala substitutions for the Arg405, Lys413, and Lys414 of wild-type LPL were constructed after the molecular dynamic simulation in the Discover_3 interface module of INSIGHT II Indicated are: wild-type LPL (pink); mutant models (blue) superimposed on wild-type LPL backbone (pink trace); residues in the hydrophobic cluster (red); N-terminal heparin-binding sites (yellow); the C-terminal heparin binding site (green); and substituted residues (orange).

structure–function relationships requires reliance upon a

model structure and functional expectations derived from

that model The crystal structure of human pancreatic

lipase has provided a framework for such directed

approaches to the study of LPL structure and function

LPL shares a high degree of primary-sequence similarity

with pancreatic lipase, and the conservation of most of

the disulfide bonds between LPL and PL suggests a

similar tertiary structure

For the two dimeric models of LPL (the closed and open

forms, Fig 1), the active dimeric form of LPL in particular

was based on the cocrystallized structures of the complexes

of human and porcine pancreatic lipases with procolipase The PL cofactor, procolipase, binds to the C-terminal domain of PL and interacts with the surface loop, presum-ably stabilizing the open form [18,19] LPL requires the cofactor apoC-II for triolein hydrolysis, but not for tributyrin [31] Despite the fact that the level of sequence conservation between apoC-II and procolipase is low, it is possible that a similar mechanism leading to a conforma-tional change also produces the LPL open form Recently, apoC-II binding to the LPL C-terminal domain has been

Fig 6 Recovery of lipase and esterase activi-ties after coexpression of S132T and WWW mutants Schematic dimeric structures of LPL

in head-to-tail configuration after cotransfec-tion of inactive LPL mutants and recovery of catalytic activity (A) Lipase activity is not detected in COS7 cells transfected with only the S132T or the WWW mutant If the cata-lytic site and the lipid recognition site of dif-ferent subunits regulate the lipase activity, then lipase activity is recovered when head-to-tail dimerization occurs after cotransfection of S132T and WWW mutants The lipase and esterase activities after transfection of vectors were assayed (B) Gray bar indicates the recovery in LPL activity after cotransfection

of S132T and WWW mutants The expression levels of wild-type and mutant LPLs were detected by Western blotting with anti-(His-tag) polyclonal antibody or 5D2 monoclonal antibody (C).

demonstrated with a cross-linking experiment using the

HL-LPL chimeric protein [21] However, a previous study

with the LPL/HL chimera enzyme had suggested that the

LPL N-terminal domain was responsible for apoC-II

binding [15] These conflicting results suggest that apoC-II

interacts simultaneously with complementary regions

located in the N-terminal domain of one subunit and the

C-terminal domain of the other This hypothesis was

suggested when Razzaghi et al demonstrated in a molecular

modeling experiment that the C-terminal domain of

apoC-II interacts with the interface of the N- and C-terminal

domains of LPL and part of the lid surface [32]

Because the functional importance of LPL’s C-terminal

domain is increasingly appreciated, the current study’s

approach to the function of the C-terminal domain is to be

derived from model structures and amino acid substitution

experiments The C-terminal domain of LPL contains

regions that contribute to heparin affinity – critical basic

residues that line up with residues in the N-terminal

heparin-binding site (Fig 1A) The truncated C-terminal

proteins of R405A, K407A, and K413A/K414A exhibit

reduced heparin affinities, whereas K381A, K422A,

K428A, and K439A proteins possess heparin affinities

comparable to wild type (Table 1) These observations are

further confirmed by monitoring the enzyme activity of the

entire molecule The R405A mutant as an LPL dimer

exhibits a low heparin affinity and a decreased lipase

activity but retains esterase activity On the other hand,

both monomeric and dimeric forms of the K413A/K414A

mutant possess reduced affinities for heparin This LPL

mutant has very low lipase and esterase activities The

model structure demonstrates that the side chains of

Lys413 and Lys414 face in opposite directions (Fig 1B);

that is, Lys413 is exposed to the surface, whereas Lys414

lies buried in the molecule Therefore, a substantial

conformational alteration occurs in the K414A mutation,

leading to the loss of lipase and esterase activities and

heparin affinity (Fig 4A and B, 5) The lipase activity of

the K413A mutant is similar to that of wild type LPL,

whereas the esterase activity is reduced to 60% of the

wild type and the model structure displays no major

conformational change (Fig 5) In the substitution model

structure, the R405A mutation results in a substantial

conformational change in the C-terminal domain, whereas

the N-terminal domain containing the active site is

unchanged (Fig 5) The overall success of the model

structures in predicting function is a confirmation of their

reliability and accuracy

Hydrophobic residues in a hydrophilic environment tend

to be held in a protein’s interior, so exposed hydrophobic

residues are uncommon The model structure of LPL

reveals that the hydrophobic cluster of Trp390, Trp393, and

Trp394 is exposed to the surface, presumably at a lipid/

water interface (Fig 1) Mutations in these hydrophobic

residues abolish the ability of the C-terminal domain to bind

or to induce VLDL, but this domain retains its capacity to

bind LRP [24,33] Therefore, the hydrophobic cluster

should be crucial for lipid substrate binding The fact that

the substitution mutants in this cluster (the WW and WWW

mutants) retain esterase activity but not the lipase activity

and that the normal affinity of these mutants for heparin

(Fig 3, Table 1) implies conservation of the overall

struc-ture of the WW and WWW mutants – indicate that these

hydrophobic residues are important in determining sub-strate specificity, a conclusion that the work of Lookene

et al [27] has already established

Of two possible dimeric structures of LPL, the head-to-head and the head-to-head-to-tail models, the studies of the chimeric proteins of hepatic lipase and LPL and the tandem repeat approach of LPL [21,34] support the head-to-tail configur-ation According to the model structures, the distance between the catalytic site (Ser132) and the substrate recognition site (Trp393) is 59.2 A˚ in the same subunit and 29.3 A˚ between the two sites on different subunits in the dimer (data not shown), which implies that a dimer with

a head-to-tail configuration is an efficient catalyst Here, we applied a unique experimental approach to examine the subunit orientation in the dimer This involved the comple-mentation of two LPL mutants, the WWW mutant lacking lipid substrate recognition and the S132T mutant lacking catalytic activity If the substrate recognition site and the catalytic site in the same polypeptide were responsible for catalyzing the lipid substrate, which is the expectation of the head-to-head model, then the lipase activity would not be expected to recover in the LPL heterodimer consisting of WWW and S132T mutant subunits But lipase activity is expected in the heterodimer of these mutants if the catalytic site and the substrate recognition site are in proximity to each other on separate subunits Approximately 50% of the lipase activity of the transfected wild-type cells is recovered after cotransfection of WWW and S132T mutants This confirms that the dimeric structure of LPL is in the head-to-tail orientation (Fig 6)

In summary, the dimer models constructed for the inactive and active forms of LPL reveal interesting features of LPL structure, including the conformational change in the active center, the critical sites for heparin binding, and the orientation of dimerization Investiga-tion into the structure–funcInvestiga-tion relaInvestiga-tionships of LPL continues to provide important information for under-standing the molecular mechanism of LPL action in lipid metabolism

A C K N O W L E D G E M E N T S

We thank Kenta Kobayashi (SGI Japan Ltd and Human Genome Center of IMS, University of Tokyo) for computer system support This work was supported in part by a Research for the Future Program Grant of The Japan Society for the Promotion of Science (II).

R E F E R E N C E S

1 Persson, B., Bengtsson-Olivecrona, G., Enerback, S., Olivecrona,

T & Jornvall, H (1989) Structural features of lipoprotein lipase Lipase family relationships, binding interactions, non-equivalence

of lipase cofactors, vitellogenin similarities and functional sub-division of lipoprotein lipase Eur J Biochem 179, 39–45.

2 Rader, D.J & Jaye, M (2000) Endothelial lipase: a new member

of the triglyceride lipase gene family Curr Opin Lipidol 11, 141– 147.

3 Santamarina-Fojo, S & Brewer, H.B Jr (1994) Lipoprotein lipase: structure, function and mechanism of action Int J Clin Laboratory Res 24, 143–147.

4 Gerdes, C., Fisher, R.M., Nicaud, V., Boer, J., Humphries, S.E., Talmud, P.J & Faergeman, O (1997) Lipoprotein lipase variants D9N and N291S are associated with increased plasma triglyceride and lower high-density lipoprotein cholesterol concentrations:

studies in the fasting and postprandial states: the European

Atherosclerosis Research Studies Circulation 96, 733–740.

5 Nordestgaard, B.G., Abildgaard, S., Wittrup, H.H., Steffensen,

R., Jensen, G & Tybjaerg-Hansen, A (1997) Heterozygous

lipo-protein lipase deficiency: frequency in the general population,

effect on plasma lipid levels, and risk of ischemic heart disease.

Circulation 96, 1737–1744.

6 Benlian, P., De Gennes, J.L., Foubert, L., Zhang, H., Gagne, S.E.

& Hayden, M (1996) Premature atherosclerosis in patients with

familial chylomicronemia caused by mutations in the lipoprotein

lipase gene N Engl J Med 335, 848–854.

7 Olivecrona, T & Bengtsson-Olivecrona, G (1993) Lipoprotein

lipase and hepatic lipase Curr Opin Lipidol 4, 187–196.

8 Beisiegel, U., Weber, W & Bengtsson-Olivecrona, G (1991)

Lipoprotein lipase enhances the binding of chylomicrons to low

density lipoprotein receptor-related protein Proc Natl Acad Sci.

USA 88, 8342–8346.

9 Strickland, D., Williams, S., Kounnas, M., Argraves, S., Inoue, I.,

Lalouel, J.-M & Chappell, D (1995) Role of the LDL

Receptor-Related Protein in Proteinase and Lipoprotein Catabolism (Gallo,

L.L., ed.) Plenum Press, New York.

10 Argraves, K.M., Battey, F.D., MacCalman, C.D., McCrae, K.R.,

Gafvels, M., Kozarsky, K.F., Chappell, D.A., Strauss, J.F., 3rd &

Strickland, D.K (1995) The very low density lipoprotein receptor

mediates the cellular catabolism of lipoprotein lipase and

urokinase-plasminogen activator inhibitor type I complexes.

J Biol Chem 270, 26550–26557.

11 Takahashi, S., Suzuki, J., Kohno, M., Oida, K., Tamai, T.,

Miyabo, S., Yamamoto, T & Nakai, T (1995) Enhancement of

the binding of triglyceride-rich lipoproteins to the very low density

lipoprotein receptor by apolipoprotein E and lipoprotein lipase.

J Biol Chem 270, 15747–15754.

12 van Tilbeurgh, H., Roussel, A., Lalouel, J.M & Cambillau, C.

(1994) Lipoprotein lipase Molecular model based on the

pan-creatic lipase x-ray structure: consequences for heparin binding

and catalysis J Biol Chem 269, 4626–4633.

13 Emmerich, J., Beg, O.U., Peterson, J., Previato, L., Brunzell, J.D.,

Brewer, H.B Jr & Santamarina-Fojo, S (1992) Human

lipopro-tein lipase Analysis of the catalytic triad by site-directed

muta-genesis of Ser-132, Asp-156, and His-241 J Biol Chem 267,

4161–4165.

14 Hata, A., Ridinger, D.N., Sutherland, S., Emi, M., Shuhua, Z.,

Myers, R.L., Ren, K., Cheng, T., Inoue, I., Wilson, D.E et al.

(1993) Binding of lipoprotein lipase to heparin Identification of

five critical residues in two distinct segments of the amino-terminal

domain J Biol Chem 268, 8447–8457.

15 Davis, R.C., Wong, H , Nikazy, J., Wang, K., H an, Q & Schotz,

M.C (1992) Chimeras of hepatic lipase and lipoprotein lipase.

Domain localization of enzyme-specific properties J Biol Chem.

267, 21499–21504.

16 Bourne, Y., Martinez, C., Kerfelec, B., Lombardo, D., Chapus, C.

& Cambillau, C (1994) Horse pancreatic lipase The crystal

structure refined at 2.3 A˚ resolution J Mol Biol 238, 709–732.

17 Winkler, F.K., D’Arcy, A & Hunziker, W (1990) Structure of

human pancreatic lipase Nature 343, 771–774.

18 van Tilbeurgh, H., Egloff, M.P., Martinez, C., Rugani, N., Verger,

R & Cambillau, C (1993) Interfacial activation of the

lipase-procolipase complex by mixed micelles revealed by X-ray

crys-tallography Nature 362, 814–820.

19 van Tilbeurgh, H., Sarda, L., Verger, R & Cambillau, C (1992)

Structure of the pancreatic lipase-procolipase complex Nature

359, 159–162.

20 Dugi, K.A., Dichek, H.L., Talley, G.D., Brewer, H.B Jr & Santamarina-Fojo, S (1992) Human lipoprotein lipase: the loop covering the catalytic site is essential for interaction with lipid substrates J Biol Chem 267, 25086–25091.

21 Hill, J.S., Yang, D., Nikazy, J., Curtiss, L.K., Sparrow, J.T & Wong, H (1998) Subdomain chimeras of hepatic lipase and lipoprotein lipase Localization of heparin and cofactor binding.

J Biol Chem 273, 30979–30984.

22 Sendak, R.A & Bensadoun, A (1998) Identification of a heparin-binding domain in the distal carboxyl-terminal region of lipoprotein lipase by site-directed mutagenesis J Lipid Res 39, 1310–1315.

23 Lutz,E.P.,Merkel,M.,Kako,Y.,Melford,K.,Radner,H.,Breslow, J.L., Bensadoun, A & Goldberg, I.J (2001) H eparin-binding defective lipoprotein lipase is unstable and causes abnormalities in lipid delivery to tissues J Clin Invest 107, 1183–1192.

24 Williams, S.E., Inoue, I., Tran, H., Fry, G.L., Pladet, M.W., Iverius, P.H., Lalouel, J.M., Chappell, D.A & Strickland, D.K (1994) The carboxyl-terminal domain of lipoprotein lipase binds

to the low density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor (LRP) and mediates binding of normal very low density lipoproteins to LRP J Biol Chem 269, 8653– 8658.

25 Nielsen, M.S., Brejning, J., Garcia, R., Zhang, H., Hayden, M.R., Vilaro, S & Gliemann, J (1997) Segments in the C-terminal folding domain of lipoprotein lipase important for binding to the low density lipoprotein receptor-related protein and to heparan sulfate proteoglycans, J Biol Chem 272, 5821–5827.

26 Herz, J & Strickland, D.K (2001) LRP: a multifunctional scavenger and signaling receptor J Clin Invest 108, 779–784.

27 Lookene, A., Groot, N.B., Kastelein, J.J., Olivecrona, G & Bruin,

T (1997) Mutation of tryptophan residues in lipoprotein lipase Effects on stability, immunoreactivity, and catalytic properties.

J Biol Chem 272, 766–772.

28 Richieri, G.V., Ogata, R.T & Kleinfeld, A.M (1999) The mea-surement of free fatty acid concentration with the fluorescent probe ADIFAB: a practical guide for the use of the ADIFAB probe Mol Cell Biochem 192, 87–94.

29 Lobo, L.I & Wilton, D.C (1997) Effect of lipid composition on lipoprotein lipase activity measured by a continuous fluorescence assay: effect of cholesterol supports an interfacial surface pene-tration model Biochem J 321, 829–835.

30 H ermoso, J., Pignol, D., Kerfelec, B., Crenon, I., Chapus, C & Fontecilla-Camps, J.C (1996) Lipase activation by nonionic detergents The crystal structure of the porcine lipase-colipase-tetraethylene glycol monooctyl ether complex J Biol Chem 271, 18007–18016.

31 Lookene, A & Bengtsson-Olivecrona, G (1993) Chymotryptic cleavage of lipoprotein lipase Identification of cleavage sites and functional studies of the truncated molecule Eur J Biochem 213, 185–194.

32 Razzaghi, H., Day, B.W., McClure, R.J & Kamboh, M.I (2001) Structure-function analysis of D9N and N291S mutations in human lipoprotein lipase using molecular modelling J Mol Graph Model 19, 487–494.

33 Chappell, D.A & Medh, J.D (1998) Receptor-mediated mechanisms of lipoprotein remnant catabolism Prog Lipid Res.

37, 393–422.

34 Wong, H., Yang, D., Hill, J.S., Davis, R.C., Nikazy, J & Schotz, M.C (1997) A molecular biology-based approach to resolve the subunit orientation of lipoprotein lipase Proc Natl Acad Sci USA 94, 5594–5598.