Abstract
N-Acylethanolamines (NAEs) are fatty acid derivatives that in animal systems include the well-known bioactive metabolites of the endocannabinoid signaling pathway. Plants use NAE signaling as well, and these bioactive molecules often have oxygenated acyl moieties. Here, we report the three-dimensional crystal structures of the signal-terminating enzyme fatty acid amide hydrolase (FAAH) from Arabidopsis in its apo and ligand-bound forms at 2.1- and 3.2-Å resolutions, respectively. This plant FAAH structure revealed features distinct from those of the only other available FAAH structure (rat). The structures disclosed that although catalytic residues are conserved with the mammalian enzyme, AtFAAH has a more open substrate-binding pocket that is partially lined with polar residues. Fundamental differences in the organization of the membrane-binding "cap" and the membrane access channel also were evident. In accordance with the observed structural features of the substrate-binding pocket, kinetic analysis showed that AtFAAH efficiently uses both unsubstituted and oxygenated acylethanolamides as substrates. Moreover, comparison of the apo and ligand-bound AtFAAH structures identified three discrete sets of conformational changes that accompany ligand binding, suggesting a unique "squeeze and lock" substrate-binding mechanism. Using molecular dynamics simulations, we evaluated these conformational changes further and noted a partial unfolding of a random-coil helix within the region 531-537 in the apo structure but not in the ligand-bound form, indicating that this region likely confers plasticity to the substrate-binding pocket. We conclude that the structural divergence in bioactive acylethanolamides in plants is reflected in part in the structural and functional properties of plant FAAHs.
Highlights
N-Acylethanolamines (NAEs) are fatty acid derivatives that in animal systems include the well-known bioactive metabolites of the endocannabinoid signaling pathway
Our results outline the structural organization of AtFAAH that supports its efficient activity toward a range of acylethanolamides that include oxygenated derivatives
Our data project that this is a result of a “malleable,” accessible, and relatively more polar substrate-binding pocket that supports a squeeze and lock substrate-binding mechanism (Fig. 11A). This is fundamentally distinct from the case for rat fatty acid amide hydrolase (FAAH) that is proposed to consist of discrete membrane access and substrate-binding channels and requires a conformational “flip” of dynamic paddle residues to correctly orient the substrate for catalysis (Fig. 11B)
Summary
Full-length AtFAAH was expressed in Escherichia coli, purified, and crystallized in the presence of the detergent n-dodecyl -D-maltoside (DDM). The entrance of the ligand-binding pocket is composed of a set of hydrophobic amino acids (Ala, Pro, Leu, Phe, Ile, and Leu55) and two charged residues (Lys and Asp58) on ␣-helices ␣1 and ␣2 of the unique N-terminal region This arrangement suggests that hydrophobic ligands access the active site through the membrane cap, which may itself be regarded as a component of the entrance channel (Fig. 3). The AtFAAH substrate-binding pocket is mostly hydrophobic, formed with amino acids from the N-terminal long loop (Met and Ala27), and ␣2–3 (Leu, Asn, and Met61), ␣17 (Val442 and Ile445), ␣18 (Ser472, Ile475, Phe476, and Phe479), ␣21 (Ile532, Thr535, Thr536, and Met539), Met256, and Thr258 (Fig. 4) These residues define a long ABC, with the portion near the entrance regarded as the MAC. Such parallel monomer orientations should enhance membrane binding and allow both subunits to function concurrently
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