Crystal Structure of Mouse Acetylcholinesterase
A PERIPHERAL SITE-OCCLUDING LOOP IN A TETRAMERIC ASSEMBLY*

Yves BourneDagger , Palmer Taylor§, Pierre E. Bougis, and Pascale Marchotparallel

From Dagger  CNRS, Unité Propre de Recherche 9039, Architecture et Fonction des Macromolécules Biologiques, Institut de Biologie et Microbiologie Structurale, F-13402 Marseille Cedex 20, France, the § Department of Pharmacology, University of California at San Diego, La Jolla, California 92093-0636, and  CNRS, Unité Mixte de Recherche 6560, Ingénierie des Protéines, Institut Fédératif de Recherche Jean Roche, Université de la Méditerranée, Faculté de Médecine Secteur Nord, F-13916 Marseille Cedex 20, France

    ABSTRACT
Top
Abstract
Introduction
References

The crystal structure of mouse acetylcholinesterase at 2.9-Å resolution reveals a tetrameric assembly of subunits with an antiparallel alignment of two canonical homodimers assembled through four-helix bundles. In the tetramer, a short Omega  loop, composed of a cluster of hydrophobic residues conserved in mammalian acetylcholinesterases along with flanking alpha -helices, associates with the peripheral anionic site of the facing subunit and sterically occludes the entrance of the gorge leading to the active center. The inverse loop-peripheral site interaction occurs within the second pair of subunits, but the peripheral sites on the two loop-donor subunits remain freely accessible to the solvent. The position and complementarity of the peripheral site-occluding loop mimic the characteristics of the central loop of the peptidic inhibitor fasciculin bound to mouse acetylcholinesterase. Tetrameric forms of cholinesterases are widely distributed in nature and predominate in mammalian brain. This structure reveals a likely mode of subunit arrangement and suggests that the peripheral site, located near the rim of the gorge, is a site for association of neighboring subunits or heterologous proteins with interactive surface loops.

    INTRODUCTION
Top
Abstract
Introduction
References

Acetylcholinesterase (AChE),1 a member of the family of proteins with an alpha /beta -hydrolase fold (1, 2), rapidly terminates cholinergic neurotransmission by hydrolysis of acetylcholine (3, 4). In mammals, AChE is encoded by a single gene, yet a multiplicity of molecular forms arise through alternative mRNA processing and association of the catalytic subunits with structural subunits. Alternative mRNA processing gives rise to three splicing options: (a) a soluble monomer without the capacity for disulfide linkage; (b) a glycophospholipid-linked form that is membrane-associated and exists as monomers and dimers; and (c) an amphiphilic form found as monomers, dimers and tetramers (in the tetramer, amphiphilic character may be lost presumably through occlusion of the hydrophobic surfaces). Further structural complexity is achieved in the tetrameric assemblies through disulfide association of the catalytic subunits with structural subunits that are either amphipathic or collagen-like, giving rise to predominant forms in brain and skeletal muscle. The tetrameric forms are dimers of dimers where one set of disulfides links with a polyproline-containing structural subunit (5) and the other set is formed between monomers (3, 4). However, there is currently little structural information about the subunit orientation in the tetramer and the association of tetramers with structural subunits.

Differences in the molecular forms of the cholinesterases are the primary determinants of their cellular disposition (3). Abnormal associations of AChE are apparent in Alzheimer's dementia, where a selective loss of the amphiphilic tetramers is observed (6, 7). AChE was suggested to associate with or to nucleate the neuritic plaques found in the disease (8-12); however, the mode of this association is unknown.

The active center of AChE, which consists of the triad Ser203-Glu334-His447 in mammals (13), is nearly centrosymmetric to the subunit and is located at the bottom of a narrow gorge (14). Inhibitors may bind at the active center or at a distant allosteric site, the peripheral anionic site, located at the gorge rim. The structure of recombinant monomeric mouse AChE (mAChE) in a complex with the peptidic inhibitor fasciculin 2 (Fas2), bound to the peripheral anionic site, provided the first mammalian cholinesterase template (15). Only slight differences were observed in the conformation of Fas2-associated mAChE compared with uncomplexed Torpedo californica AChE (TcAChE) (14). However, it was not possible to distinguish species-related differences from changes in conformation accompanying Fas2 binding. Indeed, little difference in TcAChE conformation was observed between structures of the apoenzyme (14) and the Fas2 complex (16). In addition, currently available crystal structures of AChE reveal the entrance of the active site gorge to be either occluded by a symmetry-related molecule (14, 17, 18) or sealed with high surface complementarity by Fas2 (15, 16), therefore precluding structural analysis of an unprotected peripheral anionic site region.

The crystal structure of mAChE refined to 2.9-Å resolution has good stereochemistry, with an R-factor of 21.5% for data in the 15 to 2.9-Å resolution range, and contains four mAChE monomers assembled as a tetramer, three GlcNAc moieties and one GlcNAc-beta 1,4-GlcNAc-alpha 1,6-Fuc trisaccharide moiety linked to Asn residues, four decamethonium (DECA) molecules, four phosphate groups, four glycerol molecules, and 205 water molecules in the asymmetric unit. The structure of mAChE provides significantly improved accuracy in the positions of the main and side chains of the molecule over the Fas2·mAChE structure, reveals distinctive features of the mouse enzyme, and permits direct comparison of solvent-exposed and -occluded peripheral anionic sites within the same crystal unit. More importantly, this structure highlights surface determinants that could participate in formation of oligomers upon assembly in normal and pathological states, in allosteric modulation of catalysis, and in forming heterologous cell contacts.

    EXPERIMENTAL PROCEDURES

Purification, Crystallization, and Data Collection-- Soluble mAChE expressed in HEK-293 cells was purified by affinity chromatography with desorption using either 100 mM DECA (structures A and C) or 10 mM edrophonium (EDR) (structure B); extensively dialyzed against 1 mM MES, pH 6.5, 50 mM NaCl, and 0.01% (w/v) NaN3; and prepared as described previously (19). Crystallization was achieved at 4 °C by vapor diffusion using hanging drops (4 µl) and a protein/well solution ratio of 1:1. Well solutions were made of 1.7 M NaKPO4, pH 7.0, and 10 mM CaCl2 (structure A) and 1.9 M NaKPO4, pH 7.0, and 10 mM MgCl2 (structure B), which were ice-cooled and centrifuged (10,000 × g, 4 °C) to remove precipitated material, or 0.95 M sodium citrate, pH 7.0 (structure C). Single crystals grew within 2-4 weeks to an average size of 0.2 × 0.05 × 0.05 mm whether NaKPO4 or sodium citrate was the precipitating salt.

The crystals were flash-cooled at 100 K using 5-20% glycerol in the well solution as cryoprotectant. Oscillation images were integrated with DENZO (20) and scaled and merged with SCALA (21) (Table I). Amplitude factors were generated with TRUNCATE (22). All three crystals belonged to the orthorhombic space group P212121 with unit cell dimensions a = 136.5 Å, b = 173.1 Å, and c = 224.2 Å, giving Vm values of 5.1 Å3/Da (76% solvent) and 2.55 Å3/Da (38%) for four and eight mAChE molecules, respectively, in the asymmetric unit (23).

                              
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Table I
Data collection and refinement statistics

Structure Determination and Refinement-- Initial phases for an in-house 4.5-Å resolution data set were obtained by molecular replacement using the mAChE molecule present in the structure of the Fas2·mAChE complex (Protein Data Bank 1MAH) (15) as a search model with the AMoRe program package (24). Four mAChE subunits were positioned within the asymmetric unit (correlation = 75.2%, R-factor = 29.9% in the 15 to 4.5-Å resolution range) and found to assemble as a dimer of the same dimers as seen in the Fas2·mAChE structure. Rigid-body refinement applied to the whole tetramer, each of the two dimers, and the individual subunits was then performed with X-PLOR (25) using synchrotron data between 8 and 3 Å and gave an R-factor of 33%. For 2% of the reflections against which the model was not refined, Rfree was 33%. Several cycles of Powell conjugate-gradient minimization were then performed, and electron density maps calculated with the subsequent model were inspected with TURBO-FRODO (26).

The positions of misplaced amino and carboxyl termini and of a few side chains were adjusted, and the Pro258-Gly264 portion, which was missing in the search model, was built into 2Fo - Fc and Fo - Fc electron density maps. In each of the subunits in the tetramer, a DECA molecule was fitted into a residual density observed within the active site (see "Results"). A glycerol molecule arising from the cryoprotection solution was positioned into a density found in the vicinity of Glu81, with the glycerol oxygen atoms hydrogen-bonded to the Glu452, Glu81, and Thr436 oxygen atoms and the carbon atoms in van der Waals interactions with the side chain of Met85. A phosphate group arising from the crystallization liquor was positioned between the Lys332 and Arg395 side chains, with its oxygen atoms bound to the Trp442 carbonyl oxygen and Lys332 nitrogen atoms. Since the non-crystallographic symmetry (NCS) was not restrained throughout these early stages of model building and refinement, subunits were then superimposed within each dimer, and different NCS constraints were applied along the molecule and used during all subsequent refinement steps. This model was refined with REFMAC (27), including all low resolution data. A conservative number of solvent molecules were manually added into the model; most of them were found to be located at nearly identical positions in the 2.5-Å resolution structure of TcAChE (Protein Data Bank 2ACE) (28). The conformations of some side chains were corrected using mAChE coordinates from a 2.7-Å resolution structure of the Fas2·mAChE complex.2

The final structure A comprises mAChE residues Glu4-Thr543 (subunits A and D) and residues Glu1-Cys257 and Asn265-Ala547 (subunits B and C) (see Figs. 1 and 2). High temperature factors and weak electron density include mAChE residues Glu4-Gln7 and Arg493-Pro498 in all four subunits; Pro258-Gly264 is not visible in electron density maps of subunits B and C. The r.m.s. deviation between the two mAChE subunits of a canonical dimer is 0.06 Å for tight-constraint NCS atoms, 0.16 Å for medium-constraint NCS atoms, and 0.64 Å for loose-constraint NCS atoms. Structures B and C were solved using the refined structure A (inhibitor and solvent molecules removed) as an initial model and refined to 3.1 Å. The r.m.s. deviation values for the backbone atoms and all atoms are 0.21 and 0.3 Å between structures A and B, 0.13 and 0.2 Å between structures A and C, and 0.19 and 0.26 Å between structures B and C, respectively. The stereochemistry of all three structures was analyzed with PROCHECK (29) and WHATIF (30) (Table I). Figures were generated with the programs RIBBON (31), GRASP (32), and TURBO-FRODO (26).

    RESULTS AND DISCUSSION

Overall Description of the Structure

The mAChE molecule, which consists of a 12-stranded central-mixed beta -sheet surrounded by 14 alpha -helices, has the same overall conformation as found for the Fas2·mAChE complex (15): the r.m.s. deviations between the free and complexed mAChEs are 0.5 Å for the backbone atoms and 0.6 Å for all atoms, with the largest deviations occurring in surface loops (Ala24-Gly26, Pro108-Ser110, Gln322-Leu324, Asp372-Ala374, Leu386-Pro388, and Asp491-Ser497), in the position of domain Tyr341-Glu399, and in the orientation of Tyr337.

mAChE, which is devoid of the carboxyl-terminal amphipathic helix and intersubunit disulfide-linking Cys, is monomeric in dilute solution (19), but dimeric in the Fas2·mAChE crystals, where a homodimer assembles through a tightly packed four-helix bundle (15). In the mAChE crystal, two identical homodimers assemble as a tetramer in which the two four-helix bundles are aligned antiparallel (Fig. 1). The main axes of the two dimers are tilted by ~35° from each other to form a compact, pseudo-square planar tetramer with overall dimensions of 90 × 90 × 100 Å.


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Fig. 1.   Overall view of the compact, pseudo-square planar mAChE tetramer. Panel A, ribbon diagram of the mAChE dimer of dimers viewed perpendicular to the four-helix bundle axis. Panel B, the dimer of dimers viewed parallel to the four-helix bundle axis, 90° from panel A. The italicized blue labels A and B refer to the subunits in the left dimer (displayed in dark blue), and labels C and D refer to the subunits in the right dimer (light blue) for orientation shown in panels A and C. The four-helix bundles formed by helices alpha 37,8 and alpha 10 from two subunits are displayed in magenta. The short Omega  loop Cys257-Cys272 is displayed in red, and helices alpha 16,7 and alpha 26,7 are in green. Panel C, same orientation as in panel A showing the molecular surface of dimer CD in blue, with the surfaces buried to a 1.6-Å probe radius at the dimer-dimer interface in gold. Helix alpha 16,7 in the loop region of subunit C is visible behind the ribbon trace of subunit A. The GlcNAc moiety and the GlcNAc-beta 1,4-GlcNAc-alpha 1,6-Fuc trisaccharide moiety linked to Asn350 in subunits A and D, respectively, are displayed as gray bonds with colored spheres. Secondary structure elements are specified according to Ref. 2.

In the tetramer, a short surface loop and flanking alpha -helices from subunit A of the first dimer tightly associate with the peripheral site region at the gorge entrance of the facing subunit, subunit C of the second dimer (Fig. 1). The inverse loop-peripheral site interaction involves the loop and alpha -helices of subunit D in the second dimer and the peripheral site region of subunit B in the first dimer. As a result, peripheral sites of the two loop-acceptor subunits, B and C, are occluded, whereas peripheral sites of the two loop-donor subunits, A and D, are accessible to the solvent, a feature unique to this structure. At the tetramer center, the carboxyl-terminal alpha -helices in the four-helix bundles converge at the interface. The dimer-dimer interface, which extends over 90 Å in a direction roughly perpendicular to the four-helix bundle axis, buries to a 1.6-Å probe radius, a 2500-Å2 surface area for the two pairwise dimer-dimer interfaces, an area falling in the highest range for functionally relevant crystal packing interfaces (33). Including the area buried at the four-helix bundle interface within each dimer (15), the total mAChE surface area buried within the tetramer encompasses 6000 Å2.

Detailed Description of the Structure (Structure A)

At the dimer-dimer interface, mAChE loop 257-272, a short Omega  loop (34) that is bridged by two Cys residues and contains the Pro-Pro-Gly-Gly-Ala-Gly-Gly sequence conserved in mammalian AChEs along with flanking alpha -helices alpha 16,7 and alpha 26,7 (Fig. 2), is associated with the peripheral anionic site at the gorge entrance of the facing mAChE subunit. The helix-loop-helix domain sterically occludes access to the active center gorge (Figs. 1-3). This part of the interface involves hydrophobic and polar contacts of 12 residues from each subunit (Fig. 3). The Gly260-Gly264 cluster of hydrophobic residues at the loop tip packs against peripheral site residues Tyr72, Trp286, and Tyr341, with predominant interactions between dipeptide Gly260-Gly261 and Trp286 and between dipeptide Gly261-Ala262 and Tyr341. Two discrete patches of polar interactions involve the loop extremities and flanking helices with the boundary of the peripheral anionic site and appear to form three hydrogen bonds. The guanidinyl moieties of Arg245 and Arg253, located near the amino and carboxyl termini of helix alpha 16,7, respectively, form key hydrogen bonds with the side chain carboxylate and the amide backbone nitrogen atom of Glu292, and the Gly263 nitrogen forms a hydrogen bond with the Tyr341 carbonyl oxygen. The loop shows high complementarity to the peripheral anionic site, a feature arising from the flexibility imparted by the vicinal Gly residues; limited internal stabilization of conformation is achieved from the adjacent Pro residues, with Pro258 in the cis-conformation and in van der Waals contacts with Ala262. Flexibility of the loop is evident since it cannot be seen in the absence of external stabilization, as found for subunits B and C in the tetramer (Fig. 1) and in the Fas2·mAChE complex at 3.2-Å resolution (15); only the Pro doublet is seen in the Fas2·mAChE complex at 2.7-Å resolution.2


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Fig. 2.   Overall view of the mAChE molecule and localization of the short Omega  loop relative to other secondary structure elements. The molecule (subunit D) is viewed down to the gorge entrance. Residues belonging to the peripheral anionic site (Tyr72, Asp74, Tyr124, Trp286, and Tyr341) and residues within the active center (Trp86, Ser203, Glu334, and His447) are displayed as green and gray bonds with colored spheres, respectively. The short Omega  loop Cys257-Cys272 and helices alpha 16,7 and alpha 26,7 are displayed in red and green with a yellow disulfide bridge to the left the gorge entrance. The large Omega  loop Cys69-Cys96 is displayed in orange above the gorge entrance. Helices alpha 37,8 and alpha 10, which contribute to the dimer four-helix bundle, are displayed in magenta at the bottom of the molecule. The GlcNAc moiety and the GlcNAc-beta 1,4-GlcNAc-alpha 1,6-Fuc trisaccharide moiety linked to Asn265 on the left of the molecule and to Asn350 on the right, respectively, are displayed as gray bonds with colored spheres. The labels N and C indicate the amino and carboxyl termini of the molecule, respectively. The carboxyl-terminal segment Ala544-Ala547 is not resolved in this subunit.


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Fig. 3.   Close-up view of the interaction between the loop region of subunit A and the peripheral site region of subunit C, detailing the quality of the structure. Panel A, stereo view of the 2.90-Å resolution omit Fo - Fc electron density map (contoured at 2.5sigma ) for the short Omega  loop (red) and flanking helices (dark green) of subunit A and surrounding residues in the peripheral site of subunit C. The coordinates of this region (2.5% of the total number of atoms) were omitted, and the protein coordinates were refined by simulated annealing before the phase calculation for the map. Residues belonging to the peripheral site of subunit C are displayed as light green bonds, and other residues in this subunit as light blue bonds. Residues are indicated in black for subunit A and in blue for subunit C. Broken lines indicate hydrogen bonds. Panel B, stereo view ribbon diagram of the short Omega  loop (red) and flanking helices (green) of subunit A and surrounding residues in the peripheral site of subunit C (same orientation as in panel A). The side chains arising from the loop region are displayed as green bonds with colored spheres. Residues belonging to the peripheral site of subunit C (Tyr72, Asp74, Tyr124, Trp286, and Tyr341) are displayed as dotted molecular surfaces and green bonds with colored spheres, and residues within the active center (Trp86, Ser203, Glu334, and His447) are displayed as white bonds with colored spheres.

The second region of the dimer-dimer interface is located centrosymmetric to the tetramer where the two four-helix bundles converge (Fig. 1). The carboxyl-terminal region, not seen in the Fas2·mAChE structure, is ordered sufficiently to be seen in subunits B and C, with only the carboxyl-terminal Pro548 being disordered. The two Thr543 residues at and near the carboxyl-terminal ends of helices alpha 10 of subunits A and C, respectively, face each other and are separated by only 7.5 Å. The segment from Ala544 to Ala547 is not part of helix alpha 10; instead, it deviates from the helix axis and exits the plane of the tetramer, perhaps because of charge repulsion between Glu546 residues of neighboring subunits in the tetramer. Accordingly, the carboxyl-terminal helix alpha 10 ends at Thr543, the last residue encoded by exon 4 before the region of alternative splicing (13, 19).

GlcNAc moieties are observed in two of the three consensus sequences for N-linked glycosylation, Asn350 in subunit A, also seen in the Fas2·mAChE complex (15), and Asn265 in subunits A and D, although the density is weaker. In addition, a GlcNAc-beta 1,4-GlcNAc-alpha 1,6-Fuc trisaccharide moiety is linked to Asn350 in subunit D (Figs. 1 and 2) (35, 36).

Comparison of the mAChE and Fas2·mAChE Structures

The structure of mAChE at 2.9-Å resolution provides greater delineation of the positions of the alpha -carbon and side chains than the Fas2·mAChE complex (3.2 Å) (15) and establishes several distinctive features of mAChE compared with TcAChE (Protein Data Bank 2ACE) (28). Thus, the conformations of the amino- and carboxyl-terminal segments were resolved, and the mAChE-specific positioning of the Met85 side chain in its stacking interaction with the indole of Trp86 was confirmed. The Tyr341-Ser399 rigid-body motion that was found when comparing the Fas2·mAChE and TcAChE structures is not apparent in mAChE; hence, movement of this domain is induced by Fas2 association (15).

The most prominent feature arising upon superimposition of the structures is the close resemblance of the two peripheral site-occluding loops, the short Omega  loop of mAChE subunit A and the central loop, loop II, of Fas2 bound to mAChE, in their positions and surface complementarity (Fig. 4). The mAChE loop and the tip of Fas2 loop II, although positioned roughly perpendicular with their respective Pro doublets not superimposable, overlap at the gorge entrance. Several side chains and backbone carbons of the mAChE loop mimic the side chains of Fas2 loop II in their interactions with residues in the peripheral anionic site. In particular, interaction of Gly261 in mAChE subunit A with Trp286 at the gorge entry of mAChE subunit C mimics the key interaction of Met33 in Fas2 with Trp286 in Fas2-associated mAChE; backbone atoms of Gly263-Gly264 in mAChE align with the side chain of Lys32 in Fas2; and Gly260 in mAChE establishes the same van der Waals contacts with Tyr72 as does Fas2 Leu35. Several residues in helix alpha 16,7 of mAChE subunit A also adopt positions similar to residues in bound Fas2: the side chain of Arg253 in mAChE mimics, in both position and orientation, the side chain of Arg27 in Fas2, and mAChE Gly256 forms the same van der Waals contacts with His287 as Fas2 Leu48. Hence, in the tetramer, the loops that arise from two of the subunits appear to occlude substrate access to the catalytic sites of the two other subunits, similar to steric occlusion observed in the Fas2·mAChE complex. In contrast, Fas2 loop I interacts with the large Omega  loop Cys69-Cys96 on one side of the gorge entrance, whereas mAChE helix alpha 16,7 fits into a furrow extending between the end of helix alpha 36,7 and helix alpha 27,8, on the opposite side of the mAChE gorge entrance. Since the intersubunit and Fas2-mAChE interactions differ substantially in affinity, complexation of a disulfide-linked tetramer with fasciculin would be expected to reposition residues at the interface, a rearrangement consistent with observation of equivalent affinities of the four AChE subunits for fasciculin (37).


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Fig. 4.   Comparison of the mAChE loop-peripheral site interface with the Fas2·mAChE interface. Panel A, superimposition of the short Omega  loop and flanking alpha -helices in mAChE subunit A (dark blue ribbon, green helices, and red loop) with Fas2 (yellow ribbon with orange tip of loop II) bound to mAChE (light blue molecular surface) according to all C-alpha atoms of mAChE subunit C in the tetramer and of mAChE in the Fas2·mAChE complex. The mAChE molecular surfaces buried at the loop-peripheral site and Fas2·mAChE interfaces are displayed in gold and brown, respectively. Panel B, close-up view of the similarity between the mAChE short Omega  loop and the tip of Fas2 loop II (same color codes as in panel A). Residues belonging to the peripheral site of mAChE subunit C and the side chains arising from the loop region of subunit A are displayed as green bonds with colored spheres, and the side chains arising from Fas2 are displayed as orange bonds with colored spheres. Residues are indicated in black and blue for mAChE subunits A and C, respectively, and in orange for Fas2.

The mAChE Gorge and Peripheral Anionic Site

Despite extensive dialysis (19), a DECA molecule is still present, approaching full occupancy in the active site gorges of all four mAChE subunits (Fig. 5). Superimposition of subunit A, the peripheral site of which is free of an occluding loop and totally accessible to the solvent, with TcAChE in the DECA·TcAChE complex (Protein Data Bank 1ACL) (17) shows that the proximal (N-1) and distal (N-2) quaternary ends of DECA are in van der Waals contact with the indole rings of Trp286 in the peripheral site and Trp86 in the active center and superimpose in the two structures. In mAChE, however, the 10-carbon methylene chain adopts an inverted curvature and follows the opposite wall of the gorge, a difference that involves a rotated C-5-C-6 bond and a positioning of the C-7-C-8 bond nearly 5 Å away from its position in TcAChE; hence, the C-7-C-8 portion of the methylene chain winds behind the Tyr124 ring in mAChE. The conformation of DECA in mAChE likely results from the 90° rotation of the Tyr337 phenol ring, which lies perpendicular to the gorge axis, whereas the homologous Phe330 ring in TcAChE lies parallel to the gorge axis (17, 28). The tyrosine hydroxyl, unique to mammalian AChEs, forces a different pathway for the methylene chain by its steric and polar contributions. Also, the Tyr341 ring is shifted toward the center of the gorge, ~1.5 Å removed from its position in TcAChE; hence, the hydroxyl moieties on Tyr341 and Tyr337 are separated by 3.8 Å, compared with 3 Å in TcAChE. The orientation of Tyr337, also observed in the Fas2·mAChE complex (15), could either be intrinsic to the mouse enzyme or arise from complexation with DECA or Fas2; it is, however, identical to that of Phe330 in TcAChE in complexes with various inhibitors other than DECA (17, 28). Hence, fluctuations of configuration of the active center gorge of AChE permit accommodation of a large set of active center ligands.


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Fig. 5.   Stereo views of the 2.9-Å resolution electron density maps of the DECA molecules found in the active site gorges of subunits A and C. Panel A, superimposition of DECA in subunit A (blue DECA molecule and mAChE side chains) and in the DECA·TcAChE complex (red DECA molecule and TcAChE side chains) showing the omit Fo - Fc map (contoured at 2.5sigma ) of DECA and surrounding residues in mAChE subunit A. The coordinates of this region (2.5% of total number of atoms) were omitted, and the protein coordinates were refined by simulated annealing before the phase calculation for the map. The peripheral anionic site of subunit A is free of an interacting loop and totally accessible to the solvent. The 90° rotation of mAChE Tyr337 compared with the orientation of TcAChE Phe330 and the change in the position of Tyr341 compared with TcAChE Tyr337 are evident. Panel B, superimposition of DECA in subunit C (orange DECA molecule, yellow mAChE side chains, and red loop from subunit A) and in subunit A (blue DECA molecule and mAChE side chains) showing the sigma A weighting 2Fo - Fc map (contoured at 1.2sigma ) of DECA and surrounding residues in subunit C with the loop arising from subunit A (180° from panel A). The 20° tilt of Trp286 is evident. The side chain of Tyr341, which would occlude the figure, is not displayed.

The mAChE structure provides an initial opportunity to compare exposed and occluded peripheral sites within an asymmetric unit. However, superimposition of loop-donor subunit A with loop-acceptor subunit C does not reveal large differences in conformations of the two sites. r.m.s. deviations are 0.44 and 0.77 Å for the main chain and all atoms, respectively; only the side chain of Trp286 at the gorge entrance of subunit C undergoes a 20° tilt, which may arise from the steric constraint induced by the interacting loop. However, the presence of DECA in the catalytic site of non-occluded subunit A might mask structural rearrangements expected from the unliganded peripheral site. Yet in subunit C, the bound loop partially dissociates DECA, which, although disordered, seems to adopt two discrete conformations with a hinge point near the C-4-C-5 bond. In one conformation, the proximal quaternary end of DECA interacts weakly with the indole ring of Trp286. In the second conformation, this quaternary end is displaced and flips toward the Phe338 and Ile294 side chains, some 5 Å away (Fig. 5). Residual inhibitor was observed in structures of native TcAChE, perhaps even with a tetramethylammonium-eluted enzyme (14, 17, 28). In contrast, DECA is not found in the gorge of the Fas2·mAChE complex (15), consistent with the inhibitor molecule being displaced by bound Fas2 and eliminated during dialysis of the complex prior to crystallization (19).

Other Crystal Forms of mAChE

Structures B and C are essentially identical to structure A. However, structure B contains residual EDR instead of DECA in the active site of all four subunits (data not shown). Comparison of mAChE in this structure with TcAChE in the EDR·TcAChE complex (Protein Data Bank 1ACK) (17) shows similar overall positioning of the EDR molecule, located between His447, Ser203, Tyr337, and Trp86 in mAChE; however, a 30° tilt of the EDR ring is observed, which may arise from accommodation to the Tyr337 orientation found in mAChE. There is no difference between subunits A and C, indicating that the occluding loop, which is too short to sterically destabilize the associated EDR, does not perturb it allosterically. Also, bound Fas2 does not dissociate residual EDR from the active site of the complexed enzyme.2

Structure C originates from a crystal grown in conditions different from those used for the structure A crystal and contains no bound phosphate. In subunit A, a sialic acid moiety, Sia-alpha 2,6-Gal, was fitted into an unaccounted density proximal to His287 and appears to be terminal to the oligosaccharide chain GlcNAc-beta 1,4-GlcNAc-beta 1,4-Man-alpha 1,3-Man, linked to Asn350 (data not shown) (36); the junction between the last Man and Gal moieties was not resolved, but Asn350 is located 25 Å away from His287, a value consistent with the mean distance between the two ends of an N-linked carbohydrate chain. A similar carbohydrate chain may be linked to Asn350 in subunit D, although a weaker density is observed. mAChE is composed of two species of roughly equal populations proposed to differ in their carbohydrate composition or some other post-translational modification (19). Combined gel-filtration, polyacrylamide gel electrophoresis, and isoelectric focusing experiments showed that the population of a higher mass is of a lower pI,3 an observation consistent with sialic acid in only two subunits in the mammalian tetramer (35).

Significance of the Structure

Quaternary Structure of mAChE-- A square planar model for association of catalytic and structural subunits was recently proposed based on sequence alignments, computational predictions, and mutagenesis and biochemical data (38). The tetrameric structure of mAChE (Fig. 1) largely agrees with this model. Recombinant mAChE, however, is truncated after residue 548; hence, it lacks the carboxyl-terminal sequences encoded by the alternatively spliced exons and is expressed as a monomer (19), a feature that poses the question of whether physiological forms of the enzyme would form a similar tetramer. In mouse, the alternatively spliced sequences are: (a) a 30-amino acid polar sequence encoded by the retained intron, (b) a glycophospholipid signal sequence that is cleaved at selected positions upon addition of the glycophospholipid, or (c) a 40-amino acid peptide containing an amphipathic helix and a free cysteine. Only the last splicing option allows for tetrameric assembly in situ (4, 39); assembly may be facilitated by the amphipathic helix- and polyproline-containing peptides (5). Nevertheless, truncated mAChE associates as dimers in concentrated solution and as dimers and tetramers in the crystals. Upon gel filtration at protein concentrations used for crystallization and low ionic strength (10-12 mg/ml; µ = 50 mM), mAChE elutes as a dimer, whereas at concentrations <100 µg/ml, it elutes as a monomer; tetramers were not detected under these conditions or at high ionic strengths (µ = 3 M) approaching the crystallization conditions.3 Since protein concentrations exceeding those for dimer formation are apparently required to detect tetramers, it seems unlikely that occlusion of internal sites as seen in the structure would influence kinetic studies, typically conducted at low enzyme concentrations.

Deviation of the mAChE carboxyl termini out from the tetramer plane (Fig. 1) suggests that the twisted square planar structure could accommodate, on each side and with minimal perturbation, alternatively spliced sequences serving either as attachment sites for structural subunits or as membrane-anchoring domains. Since both amphiphilic and non-amphiphilic tetramers appear to form from a single splice variant (40), discrete tetrameric species are likely where the amphipathic carboxyl-terminal sequences are either buried or exposed. Related tetrameric arrangements of catalytic subunits were recently observed in two 4.5-Å resolution crystal structures determined from two distinct crystal forms of trypsin-released tetrameric AChE from Electrophorus electricus: (a) a loose pseudo-square planar arrangement with free space in the center where the carboxyl-terminal sequences might be buried and (b) a compact square non-planar arrangement in which a folding of the tetramer along the dimer-dimer interface axis exposes the four sequences on the same side.2 Comparison of these two arrangements with that of mAChE indicates significant flexibility of the tetramer about the four-helix bundle axis and along the dimer-dimer interface axis. Hence, more than a single tetrameric arrangement may exist to accommodate the discrete carboxyl-terminal sequences.

Conformational Mobility of mAChE-- Omega loops are often important for protein stability and function and are so positioned for molecular recognition; Omega  loop lids, which are flexible until substrate or inhibitor is bound, are thought to play a role in enzymatic catalysis (34). Conformational gating provides a mechanism to recruit substrates to the active site, to exclude solvent, to sequester reactive intermediates, or to enhance substrate specificity. Conformational mobility of loop Cys69-Cys96, the large Omega  loop that is structurally homologous to the lid that sequesters the substrate in certain neutral lipases, which also show the alpha /beta -hydrolase fold (1, 2), has been proposed in gating accessibility of small molecules to the active center and in allosteric modulation of AChE catalysis (41-43). In the lipases, lid opening uncovering the catalytic site is a key feature of interfacial activation; however, the lid domain may be formed by one or more helices or surface loops that differ not only in length and sequence, but also in location relative to the alpha /beta -hydrolase core and the active site (44-49). In several alpha /beta -hydrolase proteins, the domain located between strands beta 6 and beta 7 is quite independent of the alpha /beta -hydrolase core and can accommodate large insertions such as a regulatory module (50), a putative helical lid (45), or a capping domain for the active site (51), without perturbing the core structure. The flexible short Omega  loop Cys257-Cys272, which is also located between strands beta 6 and beta 7 of mAChE and protrudes to the surface of the molecule not far from the gorge entrance (Fig. 2), and helix alpha 16,7, where several residues interact with the facing subunit in the tetramer (Figs. 1 and 3), are virtually conserved in the entire alpha /beta -hydrolase family (cf. alignment in Refs. 2, 50, and 52-55). Yet a conformational rearrangement of helix alpha 16,7 or alpha 26,7 (or both) would be required for the mAChE helix-loop-helix region to fold back and interact with the peripheral anionic site of the same mAChE subunit. Partial melting of alpha -helices into beta -sheets participates in structural reorganization of the human pancreatic lipase lid (49). Unwinding of a helical turn, refolding of a flexible connection, and cis,trans-isomerization of a Pro residue acting as a hinge point accompany positional shift of the flap in Candida rugosa lipase (47). The mobile surface loop of cytochrome c peroxidase mutant W191G contains the Pro190-Gly-Gly-Ala-Ala-Asn-Asn196 sequence, which shows striking similarity to the mAChE short Omega  loop, and is followed by an alpha -helix starting at Asn196, similar to mAChE helix alpha 26,7. Movement of the peroxidase loop involves a double-hinged rotation about Pro190 and Asn195 with a cis,trans-isomerization of Pro190 and an interchange in the positions of the Asn195 side and main chain atoms (56, 57). Hence, the sequence of the short Omega  loop and the cis-conformation of Pro258 at its base should confer conformational flexibility to the helix-loop-helix domain of mAChE.

Heterologous Associations on AChE Surfaces-- Certain brain regions contain large amounts of AChE, but are devoid of acetylcholine and its biosynthesis capacity. This disparity in localization and the appreciable secretion of AChE into extracellular space suggest that AChE may have a signaling function independent of substrate catalysis (58-60). Non-catalytic properties of AChE may also play a role in neuropathology. Colocalization of AChE and amyloid beta -peptide deposits in the brain of Alzheimer's disease patients indicates a presence, if not an active role, in amyloid plaque formation (8-11). AChE was demonstrated to accelerate the assembly of amyloid beta -peptides into Alzheimer's fibrils, with a possible involvement of the peripheral anionic site (12, 61-63).

The solution structure of amyloid beta -peptide-(1-40) shows a helix-loop-helix motif with a disordered central loop (64). Superimposition of this structure with that of the helix-loop-helix domain of mAChE (subunit A) brings several side chains in the beta -peptide and mAChE in the same position (Fig. 6). In particular, Lys16, Ala21, and Val24 in the beta -peptide superimpose with Arg247, Ala252, and Val255 in mAChE, respectively. Moreover, the side chains of His14 in the beta -peptide and Arg245 in mAChE align, a position suitable for hydrogen bonding with Glu292 in mAChE (cf. subunit C). Finally, the side chains of Glu22 in the beta -peptide and Arg253 in mAChE also align (as does the side chain of Arg27 in bound Fas2), a substitution that likely disrupts polar interactions, but not van der Waals contacts, with Pro290 and His287 in the peripheral site of mAChE. In solution, the high mobility of the two loops may bring dipeptides Val24-Gly25 and Gly29-Ala30 in the beta -peptide in the same positions as Val255-Gly256 and Gly260-Gly261 in mAChE. Hence, the amyloid beta -peptide and the mAChE helix-loop-helix domain may interact in a similar manner with the AChE peripheral anionic site, which could serve as a nucleation site to promote aggregation.


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Fig. 6.   Comparison of the mAChE helix-loop-helix domain with the human amyloid beta -peptide and the rat prion protein. Panel A, superimposition of the structures of the mAChE domain (residues 232-280) and the amyloid beta -peptide-(1-40) (1 conformer out of 20) (64) according to the C-alpha atoms of mAChE helix alpha 16,7 and beta -peptide helix alpha 15-23, with blue coils, green alpha -helices, and red (mAChE) and magenta (beta -peptide) loops. The side chains of selected residues in the mAChE domain and in the beta -peptide are displayed as green and gray bonds with colored spheres, respectively. Panel B, comparison of the mAChE domain sequence with alignment of the amyloid beta -peptide sequence (Abeta p) and the prion protein sequence (Prp; sequence 85-146, with the asterisk representing a 23-residue insertion) (64) (same color codes as in panel A). Black dots above the mAChE sequence indicate the mAChE residues that bury 10% or more of their side chain surface area at the loop-peripheral site interface. Numbering above and below the mAChE and amyloid beta -peptide sequences refers to residues whose side chains are displayed in panel A.

Conformational plasticity of the amyloid beta -peptides permits not only variable positioning of alpha -helices, but also local beta -strand structures (64-66). In the amyloid beta -peptides, as in the prion proteins, an alpha -helix to beta -sheet conversion was proposed to accompany aggregation (67). Sequence analysis revealed similarity of the amyloid protein region Gln15-Gly37 to the prion protein region Met120-Gly142 (64), a region suggested to undergo alpha -helix to beta -sheet transition in the pathogenic states (68-70). In addition to its structural similarity to the amyloid beta -peptide, the mAChE helix-loop-helix domain with its glycine cluster shows intriguing sequence similarity to the Met120-Gly142 region of the prion proteins (Fig. 6). This feature also makes rearrangement of the mAChE domain an attractive consideration.

In summary, the crystal structure of mAChE shows a tetrameric assembly of subunits; points to flexibility within the active center gorge; and reveals the peripheral anionic site, at the rim of the gorge, to be the site of association of surface loops not only from inhibitory peptides, but also from adjacent subunits. Hence, this may also be a site for heterologous protein association with AChE.

    ACKNOWLEDGEMENTS

We thank Joan Kanter (University of California at San Diego) for purification of the recombinant enzyme; Philippe Cantau and Didier Nurizzo (CNRS) for help in in-house and synchrotron data collection, respectively; and Christian Cambillau (CNRS) for interest and support. Expert assistance from Victor Lamzin (EMBL-Deutsches Elektronen-Synchrotron) and Javier Pérez (Laboratoire pour l'Utilisation du Rayonnement Electromagnétique) is much appreciated.

    FOOTNOTES

* This work was supported by United States Public Health Service Grant GM18360 and Department of Army Medical Defense Grant 17-1-8014 (to P. T.); National Science Foundation-CNRS Collaborative Project 3906 (to P. M. and P. T.); the Association Française contre les Myopathies (to P. E.B. and P. M.); and the European Union (HCMP Access to Large Installations Project, Contract CHGE-CT93-0040) and CNRS (to Y. B. and P. M. for data collection at EMBL Hamburg and the Laboratoire pour l'Utilisation du Rayonnement Electromagnétic, respectively). Part of this work was presented during the Sixth International Meeting on Cholinesterases and Related Proteins, La Jolla, CA, 1998).The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

The atomic coordinates of structure A (code 1MAA) have been deposited in the Protein Data Bank, Brookhaven National Laboratory, Upton, NY.

parallel To whom correspondence should be addressed. Fax: 33-4-9165-7595. E-mail: marchot.p{at}jean-roche.univ-mrs.fr.

The abbreviations used are: AChE, acetylcholinesterase; mAChE, recombinant mouse AChE; TcAChE, T. californica AChE; Fas2, fasciculin 2; DECA, decamethonium; EDR, edrophonium (ethyl-3-hydroxyphenyl dimethylammonium); MES, 2-(N-morpholino)ethanesulfonic acid; NCS, non-crystallographic symmetry; r.m.s., root mean square.

2 Y. Bourne, unpublished data.

3 P. Marchot, unpublished data.

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Abstract
Introduction
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