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1. Tuning the metabolic stability of visual cycle modulators through modification of an RPE65 recognition motif.

   https://doi.org/10.1021/acs.jmedchem.3c00461  

   Bassetto, Marco; Zaluski, Jordan; Li, Bowen; Zhang, Jianye; Badiee, Mohsen; Kiser Philip; Tochtrop, Gregory P (January 2023, Journal of medicinal chemistry)

   In the eye, the isomerization of all-trans-retinal to 11-cis-retinal is accomplished by a metabolic pathway termed the visual cycle that is critical for vision. RPE65 is the essential trans–cis isomerase of this pathway. Emixustat, a retinoid-mimetic RPE65 inhibitor, was developed as a therapeutic visual cycle modulator and used for the treatment of retinopathies. However, pharmacokinetic liabilities limit its further development including: (1) metabolic deamination of the γ-amino-α-aryl alcohol, which mediates targeted RPE65 inhibition, and (2) unwanted long-lasting RPE65 inhibition. We sought to address these issues by more broadly defining the structure–activity relationships of the RPE65 recognition motif via the synthesis of a family of novel derivatives, which were tested in vitro and in vivo for RPE65 inhibition. We identified a potent secondary amine derivative with resistance to deamination and preserved RPE65 inhibitory activity. Our data provide insights into activity-preserving modifications of the emixustat molecule that can be employed to tune its pharmacological properties. 

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2. Chromophore hydrolysis and release from photoactivated rhodopsin in native membranes

   https://doi.org/10.1073/pnas.2213911119  

   Hong, John D.; Salom, David; Kochman, Michał Andrzej; Kubas, Adam; Kiser, Philip D.; Palczewski, Krzysztof (November 2022, Proceedings of the National Academy of Sciences)

   For sustained vision, photoactivated rhodopsin (Rho*) must undergo hydrolysis and release of all- trans -retinal, producing substrate for the visual cycle and apo-opsin available for regeneration with 11- cis -retinal. The kinetics of this hydrolysis has yet to be described for rhodopsin in its native membrane environment. We developed a method consisting of simultaneous denaturation and chromophore trapping by isopropanol/borohydride, followed by exhaustive protein digestion, complete extraction, and liquid chromatography–mass spectrometry. Using our method, we tracked Rho* hydrolysis, the subsequent formation of N -retinylidene-phosphatidylethanolamine ( N -ret-PE) adducts with the released all- trans -retinal, and the reduction of all- trans -retinal to all- trans -retinol. We found that hydrolysis occurred faster in native membranes than in detergent micelles typically used to study membrane proteins. The activation energy of the hydrolysis in native membranes was determined to be 17.7 ± 2.4 kcal/mol. Our data support the interpretation that metarhodopsin II, the signaling state of rhodopsin, is the primary species undergoing hydrolysis and release of its all- trans -retinal. In the absence of NADPH, free all- trans -retinal reacts with phosphatidylethanolamine (PE), forming a substantial amount of N -ret-PE (∼40% of total all- trans -retinal at physiological pH), at a rate that is an order of magnitude faster than Rho* hydrolysis. However, N -ret-PE formation was highly attenuated by NADPH-dependent reduction of all- trans -retinal to all- trans -retinol. Neither N -ret-PE formation nor all- trans -retinal reduction affected the rate of hydrolysis of Rho*. Our study provides a comprehensive picture of the hydrolysis of Rho* and the release of all- trans -retinal and its reentry into the visual cycle, a process in which alteration can lead to severe retinopathies. 

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3. Reassignment of the human aldehyde dehydrogenase ALDH8A1 (ALDH12) to the kynurenine pathway in tryptophan catabolism

   https://doi.org/10.1074/jbc.RA118.003320  

   Davis, Ian; Yang, Yu; Wherritt, Daniel; Liu, Aimin (July 2018, Journal of Biological Chemistry)

   The kynurenine pathway is the primary route for L-tryptophan degradation in mammals. Intermediates and side products of this pathway are involved in immune response and neurodegenerative diseases. This makes the study of enzymes, especially those from mammalian sources, of the kynurenine pathway worthwhile. Recent studies on a bacterial version of an enzyme of this pathway, 2-aminomuconate semialdehyde (2-AMS) dehydrogenase (AMSDH), have provided a detailed understanding of the catalytic mechanism and identified residues conserved for muconate semialdehyde recognition and activation. Findings from the bacterial enzyme have prompted the reconsideration of the function of a previously identified human aldehyde dehydrogenase, ALDH8A1 (or ALDH12), which was annotated as a retinal dehydrogenase based on its ability to preferentially oxidize 9-cis-retinal over trans-retinal. Here, we provide compelling bioinformatics and experimental evidence that human ALDH8A1 should be reassigned to the missing 2-AMS dehydrogenase of the kynurenine metabolic pathway. For the first time, the product of the semialdehyde oxidation by AMSDH is also revealed by NMR and high-resolution MS. We found that ALDH8A1 catalyzes the NAD+ -dependent oxidation of 2- AMS with a catalytic efficiency equivalent to that of AMSDH from the bacterium Pseudomonas fluorescens. Substitution of active-site residues required for substrate recognition, binding, and isomerization in the bacterial enzyme resulted in human ALDH8A1 variants with 160-fold increased Km or no detectable activity. In conclusion, this molecular study establishes an additional enzymatic step in an important human pathway for tryptophan catabolism. 

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4. Two-photon autofluorescence lifetime assay of rabbit photoreceptors and retinal pigment epithelium during light-dark visual cycles in rabbit retina

   https://doi.org/10.1364/BOE.511806  

   Nguyen, Trung_Duc; Chen, Yuan-I; Nguyen, Anh-Thu; Yonas, Siem; Sripati, Manasa_P; Kuo, Yu-An; Hong, Soonwoo; Litvinov, Mitchell; He, Yujie; Yeh, Hsin-Chih; et al (April 2024, Biomedical Optics Express)

   Two-photon excited fluorescence (TPEF) is a powerful technique that enables the examination of intrinsic retinal fluorophores involved in cellular metabolism and the visual cycle. Although previous intensity-based TPEF studies in non-human primates have successfully imaged several classes of retinal cells and elucidated aspects of both rod and cone photoreceptor function, fluorescence lifetime imaging (FLIM) of the retinal cells under light-dark visual cycle has yet to be fully exploited. Here we demonstrate a FLIM assay of photoreceptors and retinal pigment epithelium (RPE) that reveals key insights into retinal physiology and adaptation. We found that photoreceptor fluorescence lifetimes increase and decrease in sync with light and dark exposure, respectively. This is likely due to changes in all-trans-retinol and all-trans-retinal levels in the outer segments, mediated by phototransduction and visual cycle activity. During light exposure, RPE fluorescence lifetime was observed to increase steadily over time, as a result of all-trans-retinol accumulation during the visual cycle and decreasing metabolism caused by the lack of normal perfusion of the sample. Our system can measure the fluorescence lifetime of intrinsic retinal fluorophores on a cellular scale, revealing differences in lifetime between retinal cell classes under different conditions of light and dark exposure. 

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5. Carotenoid cleavage enzymes evolved convergently to generate the visual chromophore

   https://doi.org/10.1038/s41589-024-01554-z  

   Solano, Yasmeen_J; Everett, Michael_P; Dang, Kelly_S; Abueg, Jude; Kiser, Philip_D (February 2024, Nature Chemical Biology)

   Abstract The retinal light response in animals originates from the photoisomerization of an opsin-coupled 11-cis-retinaldehyde chromophore. This visual chromophore is enzymatically produced through the action of carotenoid cleavage dioxygenases. Vertebrates require two carotenoid cleavage dioxygenases, β-carotene oxygenase 1 and retinal pigment epithelium 65 (RPE65), to form 11-cis-retinaldehyde from carotenoid substrates, whereas invertebrates such as insects use a single enzyme known as Neither Inactivation Nor Afterpotential B (NinaB). RPE65 and NinaB coupletrans–cisisomerization with hydrolysis and oxygenation, respectively, but the mechanistic relationship of their isomerase activities remains unknown. Here we report the structure of NinaB, revealing details of its active site architecture and mode of membrane binding. Structure-guided mutagenesis studies identify a residue cluster deep within the NinaB substrate-binding cleft that controls its isomerization activity. Our data demonstrate that isomerization activity is mediated by distinct active site regions in NinaB and RPE65—an evolutionary convergence that deepens our understanding of visual system diversity. 

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