Aromatic Residues in the Substrate Cleft of RPE65 Protein Govern Retinol Isomerization and Modulate Its Progression

Preethi Chander,Susan Gentleman,Eugenia Poliakov,T.Michael Redmond

doi:10.1074/jbc.m112.364596

Preethi Chander, Susan Gentleman + Show 2 more

Open Access

https://doi.org/10.1074/jbc.m112.364596

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Abstract

Previously, we showed that mutating RPE65 residue Phe-103 preferentially produces 13-cis-retinol instead of 11-cis-retinol, supporting a carbocation/radical cation mechanism of retinol isomerization. We asked whether this modulation of specificity can occur with residues other than Phe-103 and what role it plays in substrate binding and isomerization. We modeled the substrate-binding cleft of RPE65 to identify residues lining its surface. Many are phenylalanines and tyrosines, including three Phe residues (Phe-61, Phe-312, and Phe-526) forming an arch-like arrangement astride the cleft and Tyr-338. Also, Phe-418 sits at the neck of the cleft, lending a bend to the volume enclosed by the cleft. All mutations of Phe-61, Phe-312, and Phe-418 result in severely impaired or inactive enzyme. However, mutation of Phe-526 and Tyr-338, like Phe-103, decreases 11-cis-retinol formation, whereas increasing the 13-cis isomer. Significantly, 2 of these 3 residues, Phe-103 and Tyr-338, are located on putatively mobile interstrand loops. We propose that residual densities located in the binding cleft of the RPE65 structure represents a post-cleavage snapshot consistent not only with a fatty acid product, as originally modeled, but also an 11-cis-retinol product. Substrate docking simulations permit 11-cis- or 13-cis-retinyl ester binding in this relatively closed cleft, with the latter favored in F103L, F526A, and Y338A mutant structures, but prohibit binding of all-trans-retinyl ester, suggesting that isomerization occurs early in the temporal sequence, with O-alkyl ester cleavage occurring later. These findings provide insight into the mechanism of isomerization central to the visual cycle.

Highlights

RPE65 retinol isomerohydrolase is essential for vision, but its catalytic mechanism is poorly understood
We demonstrate, using site-directed mutagenesis and structure-based modeling, that an assemblage of aromatic residues in the substrate-binding cleft of RPE65 governs the progression and specificity of retinoid isomerization by this enzyme
These data extend our previous conclusions [8] that RPE65 utilizes a cationic intermediate in its mechanism by showing that multiple aromatic residues contribute to the retinyl moiety-binding cavity within which isomerization occurs

Summary

Background

RPE65 retinol isomerohydrolase is essential for vision, but its catalytic mechanism is poorly understood. Substrate docking simulations permit 11-cis- or 13-cis-retinyl ester binding in this relatively closed cleft, with the latter favored in F103L, F526A, and Y338A mutant structures, but prohibit binding of all-trans-retinyl ester, suggesting that isomerization occurs early in the temporal sequence, with O-alkyl ester cleavage occurring later These findings provide insight into the mechanism of isomerization central to the visual cycle. We concluded that the mechanism underlying the leaky isomerization implicates a carbocation or a radical cation intermediate with loss of polyene bond order allowing for production of either 11-cis-ROL or 13-cisROL by RPE65 and that ultimate specificity for 11-cis isomers occurs downstream by a process of mass action applied by 11-cis-specific binding proteins such as CRALBP and apoprotein opsins [8], as suggested previously [9, 11]. Docking was investigated in mutant RPE65 models to clarify possible mechanisms for the changes in activities seen in these mutants

EXPERIMENTAL PROCEDURES

RESULTS

DISCUSSION