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373 results on '"von Lintig, Johannes"'

5. The Structural and Biochemical Basis of Apocarotenoid Processing by β-Carotene Oxygenase-2.

Author

Bandara, Sepalika, Thomas, Linda, Ramkumar, Srinivasagan, Khadka, Nimesh, Kiser, Philip, Golczak, Marcin, and von Lintig, Johannes

Subjects
Alcohols, Aldehydes, Carboxylic Acids, Carotenoids, Catalysis, Cloning, Molecular, Dioxygenases, Escherichia coli, Isotope Labeling, Lipid Metabolism, Models, Molecular, Molecular Structure, Oxidative Stress, Oxygen Isotopes, Oxygenases, Structure-Activity Relationship, Vitamin A, beta Carotene
Abstract

In mammals, carotenoids are converted by two carotenoid cleavage oxygenases into apocarotenoids, including vitamin A. Although knowledge about β-carotene oxygenase-1 (BCO1) and vitamin A metabolism has tremendously increased, the function of β-carotene oxygenase-2 (BCO2) remains less well-defined. We here studied the role of BCO2 in the metabolism of long chain β-apocarotenoids, which recently emerged as putative regulatory molecules in mammalian biology. We showed that recombinant murine BCO2 converted the alcohol, aldehyde, and carboxylic acid of a β-apocarotenoid substrate by oxidative cleavage at position C9,C10 into a β-ionone and a diapocarotenoid product. Chain length variation (C20 to C40) and ionone ring site modifications of the apocarotenoid substrate did not impede catalytic activity or alter the regioselectivity of the double bond cleavage by BCO2. Isotope labeling experiments revealed that the double bond cleavage of an apocarotenoid followed a dioxygenase reaction mechanism. Structural modeling and site directed mutagenesis identified amino acid residues in the substrate tunnel of BCO2 that are critical for apocarotenoid binding and catalytic processing. Mice deficient for BCO2 accumulated apocarotenoids in their livers, indicating that the enzyme engages in apocarotenoid metabolism. Together, our study provides novel structural and functional insights into BCO2 catalysis and establishes the enzyme as a key component of apocarotenoid homeostasis in mice.

Published
2021

7. The human mitochondrial enzyme BCO2 exhibits catalytic activity toward carotenoids and apocarotenoids.

Author

Thomas, Linda, Bandara, Sepalika, Parmar, Vipulkumar, Srinivasagan, Ramkumar, Khadka, Nimesh, Golczak, Marcin, Kiser, Philip, and von Lintig, Johannes

Subjects
BCO2, Vision, apocarotenoids, carotenoid apocarotenoid, carotenoids, dioxygenase, macular pigments, metabolism, retina, vision, β-carotene-oxygenase 2 (BCO2), Animals, Binding Sites, Biocatalysis, Carotenoids, Dioxygenases, Humans, Mice, Mitochondria, Molecular Dynamics Simulation, Protein Isoforms, Protein Structure, Tertiary, RNA Splicing, Recombinant Proteins, Retina, Solubility, Stereoisomerism, Zeaxanthins
Abstract

The enzyme β-carotene oxygenase 2 (BCO2) converts carotenoids into more polar metabolites. Studies in mammals, fish, and birds revealed that BCO2 controls carotenoid homeostasis and is involved in the pathway for vitamin A production. However, it is controversial whether BCO2 function is conserved in humans, because of a 4-amino acid long insertion caused by a splice acceptor site polymorphism. We here show that human BCO2 splice variants, BCO2a and BCO2b, are expressed as pre-proteins with mitochondrial targeting sequence (MTS). The MTS of BCO2a directed a green fluorescent reporter protein to the mitochondria when expressed in ARPE-19 cells. Removal of the MTS increased solubility of BCO2a when expressed in Escherichia coli and rendered the recombinant protein enzymatically active. The expression of the enzymatically active recombinant human BCO2a was further improved by codon optimization and its fusion with maltose-binding protein. Introduction of the 4-amino acid insertion into mouse Bco2 did not impede the chimeric enzymes catalytic proficiency. We further showed that the chimeric BCO2 displayed broad substrate specificity and converted carotenoids into two ionones and a central C14-apocarotendial by oxidative cleavage reactions at C9,C10 and C9,C10. Thus, our study demonstrates that human BCO2 is a catalytically competent enzyme. Consequently, information on BCO2 becomes broadly applicable in human biology with important implications for the physiology of the eyes and other tissues.

Published
2020

8. Structural basis for carotenoid cleavage by an archaeal carotenoid dioxygenase

Author

Daruwalla, Anahita, Zhang, Jianye, Lee, Ho Jun, Khadka, Nimesh, Farquhar, Erik R, Shi, Wuxian, von Lintig, Johannes, and Kiser, Philip D

Subjects
Underpinning research, 1.1 Normal biological development and functioning, Archaea, Archaeal Proteins, Bacterial Proteins, Carotenoids, Catalysis, Catalytic Domain, Dioxygenases, Substrate Specificity, Synechocystis, beta-apo-14 '-carotenal, regioselectivity, RPE65, nonheme iron, apocarotenoid, β-apo-14′-carotenal
Abstract

Apocarotenoids are important signaling molecules generated from carotenoids through the action of carotenoid cleavage dioxygenases (CCDs). These enzymes have a remarkable ability to cleave carotenoids at specific alkene bonds while leaving chemically similar sites within the polyene intact. Although several bacterial and eukaryotic CCDs have been characterized, the long-standing goal of experimentally visualizing a CCD-carotenoid complex at high resolution to explain this exquisite regioselectivity remains unfulfilled. CCD genes are also present in some archaeal genomes, but the encoded enzymes remain uninvestigated. Here, we address this knowledge gap through analysis of a metazoan-like archaeal CCD from Candidatus Nitrosotalea devanaterra (NdCCD). NdCCD was active toward β-apocarotenoids but did not cleave bicyclic carotenoids. It exhibited an unusual regiospecificity, cleaving apocarotenoids solely at the C14'-C13' alkene bond to produce β-apo-14'-carotenals. The structure of NdCCD revealed a tapered active site cavity markedly different from the broad active site observed for the retinal-forming Synechocystis apocarotenoid oxygenase (SynACO) but similar to the vertebrate retinoid isomerase RPE65. The structure of NdCCD in complex with its apocarotenoid product demonstrated that the site of cleavage is defined by interactions along the substrate binding cleft as well as selective stabilization of reaction intermediates at the scissile alkene. These data on the molecular basis of CCD catalysis shed light on the origins of the varied catalytic activities found in metazoan CCDs, opening the possibility of modifying their activity through rational chemical or genetic approaches.

Published
2020

12. Evidence for distinct rate-limiting steps in the cleavage of alkenes by carotenoid cleavage dioxygenases

Author

Khadka, Nimesh, Farquhar, Erik R, Hill, Hannah E, Shi, Wuxian, von Lintig, Johannes, and Kiser, Philip D

Subjects
Inorganic Chemistry, Chemical Sciences, Alkenes, Binding Sites, Biocatalysis, Catalytic Domain, Crystallography, X-Ray, Deuterium Exchange Measurement, Hydrogen-Ion Concentration, Iron, Kinetics, Mutagenesis, Site-Directed, Neurospora crassa, Oxygenases, Solvents, Sphingomonadaceae, Substrate Specificity, enzyme kinetics, iron, crystallography, carotenoid, dioxygenase, non-heme iron, O-2 activation, solvent isotope effect, stilbenoid, X-ray absorption spectroscopy, O2 activation, Biological Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences
Abstract

Carotenoid cleavage dioxygenases (CCDs) use a nonheme Fe(II) cofactor to split alkene bonds of carotenoid and stilbenoid substrates. The iron centers of CCDs are typically five-coordinate in their resting states, with solvent occupying an exchangeable site. The involvement of this iron-bound solvent in CCD catalysis has not been experimentally addressed, but computational studies suggest two possible roles. 1) Solvent dissociation provides a coordination site for O2, or 2) solvent remains bound to iron but changes its equilibrium position to allow O2 binding and potentially acts as a proton source. To test these predictions, we investigated isotope effects (H2O versus D2O) on two stilbenoid-cleaving CCDs, Novosphingobium aromaticivorans oxygenase 2 (NOV2) and Neurospora crassa carotenoid oxygenase 1 (CAO1), using piceatannol as a substrate. NOV2 exhibited an inverse isotope effect (k H/k D ∼ 0.6) in an air-saturated buffer, suggesting that solvent dissociates from iron during the catalytic cycle. By contrast, CAO1 displayed a normal isotope effect (k H/k D ∼ 1.7), suggesting proton transfer in the rate-limiting step. X-ray absorption spectroscopy on NOV2 and CAO1 indicated that the protonation states of the iron ligands are unchanged within pH 6.5-8.5 and that the Fe(II)-aquo bond is minimally altered by substrate binding. We pinpointed the origin of the differential kinetic behaviors of NOV2 and CAO1 to a single amino acid difference near the solvent-binding site of iron, and X-ray crystallography revealed that the substitution alters binding of diffusible ligands to the iron center. We conclude that solvent-iron dissociation and proton transfer are both associated with the CCD catalytic mechanism.

Published
2019

14. Preparation and characterization of metal-substituted carotenoid cleavage oxygenases.

Author

Sui, Xuewu, Farquhar, Erik, Hill, Hannah, von Lintig, Johannes, Shi, Wuxian, and Kiser, Philip

Subjects
Cobalt substitution, Crystal structure, Non-heme iron enzyme, X-ray absorption spectroscopy, Binding Sites, Catalysis, Cobalt, Crystallography, X-Ray, Oxygenases, Synechocystis, X-Ray Absorption Spectroscopy
Abstract

Carotenoid cleavage oxygenases (CCO) are non-heme iron enzymes that catalyze oxidative cleavage of alkene bonds in carotenoid and stilbenoid substrates. Previously, we showed that the iron cofactor of CAO1, a resveratrol-cleaving member of this family, can be substituted with cobalt to yield a catalytically inert enzyme useful for trapping active site-bound stilbenoid substrates for structural characterization. Metal substitution may provide a general method for identifying the natural substrates for CCOs in addition to facilitating structural and biophysical characterization of CCO-carotenoid complexes under normal aerobic conditions. Here, we demonstrate the general applicability of cobalt substitution in a prototypical carotenoid cleaving CCO, apocarotenoid oxygenase (ACO) from Synechocystis. Among the non-native divalent metals investigated, cobalt was uniquely able to stably occupy the ACO metal binding site and inhibit catalysis. Analysis by X-ray crystallography and X-ray absorption spectroscopy demonstrate that the Co(II) forms of both ACO and CAO1 exhibit a close structural correspondence to the native Fe(II) enzyme forms. Hence, cobalt substitution is an effective strategy for generating catalytically inert but structurally intact forms of CCOs.

Published
2018

15. Structure and Spectroscopy of Alkene-Cleaving Dioxygenases Containing an Atypically Coordinated Non-Heme Iron Center.

Author

Sui, Xuewu, Weitz, Andrew, Farquhar, Erik, Badiee, Mohsen, Banerjee, Surajit, von Lintig, Johannes, Tochtrop, Gregory, Palczewski, Krzysztof, Hendrich, Michael, and Kiser, Philip

Subjects
Alkenes, Dioxygenases, Heme, Protein Conformation
Abstract

Carotenoid cleavage oxygenases (CCOs) are non-heme iron enzymes that catalyze scission of alkene groups in carotenoids and stilbenoids to form biologically important products. CCOs possess a rare four-His iron center whose resting-state structure and interaction with substrates are incompletely understood. Here, we address this knowledge gap through a comprehensive structural and spectroscopic study of three phyletically diverse CCOs. The crystal structure of a fungal stilbenoid-cleaving CCO, CAO1, reveals strong similarity between its iron center and those of carotenoid-cleaving CCOs, but with a markedly different substrate-binding cleft. These enzymes all possess a five-coordinate high-spin Fe(II) center with resting-state Fe-His bond lengths of ∼2.15 Å. This ligand set generates an iron environment more electropositive than those of other non-heme iron dioxygenases as observed by Mössbauer isomer shifts. Dioxygen (O2) does not coordinate iron in the absence of substrate. Substrates bind away (∼4.7 Å) from the iron and have little impact on its electronic structure, thus excluding coordination-triggered O2 binding. However, substrate binding does perturb the spectral properties of CCO Fe-NO derivatives, indicating proximate organic substrate and O2-binding sites, which might influence Fe-O2 interactions. Together, these data provide a robust description of the CCO iron center and its interactions with substrates and substrate mimetics that illuminates commonalities as well as subtle and profound structural differences within the CCO family.

Published
2017

16. Mutations in the Spliceosome Component CWC27 Cause Retinal Degeneration with or without Additional Developmental Anomalies.

Author

Xu, Mingchu, Xie, Yajing, Abouzeid, Hana, Gordon, Christopher, Fiorentino, Alessia, Sun, Zixi, Lehman, Anna, Osman, Ihab, Dharmat, Rachayata, Riveiro-Alvarez, Rosa, Bapst-Wicht, Linda, Babino, Darwin, Arno, Gavin, Busetto, Virginia, Zhao, Li, Li, Hui, Lopez-Martinez, Miguel, Azevedo, Liliana, Hubert, Laurence, Pontikos, Nikolas, Eblimit, Aiden, Lorda-Sanchez, Isabel, Kheir, Valeria, Plagnol, Vincent, Oufadem, Myriam, Soens, Zachry, Yang, Lizhu, Bole-Feysot, Christine, Pfundt, Rolph, Allaman-Pillet, Nathalie, Nitschké, Patrick, Cheetham, Michael, Lyonnet, Stanislas, Agrawal, Smriti, Li, Huajin, Pinton, Gaëtan, Michaelides, Michel, Besmond, Claude, Li, Yumei, Yuan, Zhisheng, von Lintig, Johannes, Webster, Andrew, Le Hir, Hervé, Stoilov, Peter, Amiel, Jeanne, Hardcastle, Alison, Ayuso, Carmen, Sui, Ruifang, Chen, Rui, Allikmets, Rando, and Schorderet, Daniel

Subjects
CRISPR-Cas9, CWC27, brachydachtyly, craniofacial defects, neurological defects, retinal degeneration, short stature, spliceosome, syndrome, Abnormalities, Multiple, Adolescent, Animals, Child, Child, Preschool, Cyclophilins, Female, Humans, Male, Mice, Mutation, Pedigree, Peptidylprolyl Isomerase, Retinal Degeneration, Young Adult
Abstract

Pre-mRNA splicing factors play a fundamental role in regulating transcript diversity both temporally and spatially. Genetic defects in several spliceosome components have been linked to a set of non-overlapping spliceosomopathy phenotypes in humans, among which skeletal developmental defects and non-syndromic retinitis pigmentosa (RP) are frequent findings. Here we report that defects in spliceosome-associated protein CWC27 are associated with a spectrum of disease phenotypes ranging from isolated RP to severe syndromic forms. By whole-exome sequencing, recessive protein-truncating mutations in CWC27 were found in seven unrelated families that show a range of clinical phenotypes, including retinal degeneration, brachydactyly, craniofacial abnormalities, short stature, and neurological defects. Remarkably, variable expressivity of the human phenotype can be recapitulated in Cwc27 mutant mouse models, with significant embryonic lethality and severe phenotypes in the complete knockout mice while mice with a partial loss-of-function allele mimic the isolated retinal degeneration phenotype. Our study describes a retinal dystrophy-related phenotype spectrum as well as its genetic etiology and highlights the complexity of the spliceosomal gene network.

Published
2017

23. Structural Insights into the Drosophila melanogaster Retinol Dehydrogenase, a Member of the Short-Chain Dehydrogenase/Reductase Family.

Author

Hofmann, Lukas, Tsybovsky, Yaroslav, Alexander, Nathan, Babino, Darwin, Leung, Nicole, Banerjee, Surajit, von Lintig, Johannes, Palczewski, Krzysztof, and Montell, Craig

Subjects
Alcohol Oxidoreductases, Animals, Crystallization, Crystallography, X-Ray, Drosophila Proteins, Drosophila melanogaster, Genetic Complementation Test, Humans, Models, Molecular, Mutation, NAD, Oxidoreductases, Protein Binding, Protein Conformation, Protein Multimerization
Abstract

The 11-cis-retinylidene chromophore of visual pigments isomerizes upon interaction with a photon, initiating a downstream cascade of signaling events that ultimately lead to visual perception. 11-cis-Retinylidene is regenerated through enzymatic transformations collectively called the visual cycle. The first and rate-limiting enzymatic reaction within this cycle, i.e., the reduction of all-trans-retinal to all-trans-retinol, is catalyzed by retinol dehydrogenases. Here, we determined the structure of Drosophila melanogaster photoreceptor retinol dehydrogenase (PDH) isoform C that belongs to the short-chain dehydrogenase/reductase (SDR) family. This is the first reported structure of a SDR that possesses this biologically important activity. Two crystal structures of the same enzyme grown under different conditions revealed a novel conformational change of the NAD+ cofactor, likely representing a change during catalysis. Amide hydrogen-deuterium exchange of PDH demonstrated changes in the structure of the enzyme upon dinucleotide binding. In D. melanogaster, loss of PDH activity leads to photoreceptor degeneration that can be partially rescued by transgenic expression of human RDH12. Based on the structure of PDH, we analyzed mutations causing Leber congenital amaurosis 13 in a homology model of human RDH12 to obtain insights into the molecular basis of RDH12 disease-causing mutations.

Published
2016

24. The Biochemical Basis of Vitamin A3 Production in Arthropod Vision.

Author

Babino, Darwin, Golczak, Marcin, Kiser, Philip, Wyss, Adrian, Palczewski, Krzysztof, and von Lintig, Johannes

Subjects
Animals, Arthropods, Catalysis, Oxidation-Reduction, Vitamin A
Abstract

Metazoan photochemistry involves cis-trans isomerization of a retinylidene chromophore bound to G protein coupled receptors. Successful production of chromophores is critical for photoreceptor function and survival. For chromophore production, animals have to choose from more than 600 naturally occurring carotenoids and process them by oxidative cleavage and geometric isomerization of double bonds. Vertebrates employ three carotenoid cleavage oxygenases to tailor the carotenoid precursor in the synthesis of 11-cis-retinal (vitamin A1). Lepidoptera (butterfly and moth) possess only one such enzyme, NinaB, which faces the challenge to catalyze these reactions in unison to produce 11-cis-3-hydroxy-retinal (vitamin A3). We here showed that key to this multitasking is a bipartite substrate recognition site that conveys regio- and stereoselectivity for double bond processing. One side performed the specific C11, C12 cis-isomerization and preferentially binds 3-OH-β-ionone rings sites. The other side maintained a trans configuration in the resulting product and preferentially binds noncanonical ionone ring sites. Concurrent binding of carotenoids containing two cyclohexyl rings to both domains is required for specific oxidative cleavage at position C15, C15 of the substrate. The unique reaction sequence follows a dioxygenase mechanism with a carbocation/radical intermediate. This ingenious quality control system guarantees 11-cis-3-hydroxy-retinal production, the essential retinoid for insect (vitamin A3) vision.

Published
2016

25. Utilization of Dioxygen by Carotenoid Cleavage Oxygenases.

Author

Sui, Xuewu, Golczak, Marcin, Zhang, Jianye, Kleinberg, Katie, von Lintig, Johannes, Palczewski, Krzysztof, and Kiser, Philip

Subjects
carotenoid, enzyme, enzyme catalysis, enzyme mechanism, enzyme structure, retinal metabolism, retinoid, retinol, Animals, Bacterial Proteins, Carotenoids, Cattle, Dioxygenases, Intramolecular Oxidoreductases, Oxygen, Resveratrol, Stilbenes, Synechocystis
Abstract

Carotenoid cleavage oxygenases (CCOs) are non-heme, Fe(II)-dependent enzymes that participate in biologically important metabolic pathways involving carotenoids and apocarotenoids, including retinoids, stilbenes, and related compounds. CCOs typically catalyze the cleavage of non-aromatic double bonds by dioxygen (O2) to form aldehyde or ketone products. Expressed only in vertebrates, the RPE65 sub-group of CCOs catalyzes a non-canonical reaction consisting of concerted ester cleavage and trans-cis isomerization of all-trans-retinyl esters. It remains unclear whether the former group of CCOs functions as mono- or di-oxygenases. Additionally, a potential role for O2 in catalysis by the RPE65 group of CCOs has not been evaluated to date. Here, we investigated the pattern of oxygen incorporation into apocarotenoid products of Synechocystis apocarotenoid oxygenase. Reactions performed in the presence of (18)O-labeled water and (18)O2 revealed an unambiguous dioxygenase pattern of O2 incorporation into the reaction products. Substitution of Ala for Thr at position 136 of apocarotenoid oxygenase, a site predicted to govern the mono- versus dioxygenase tendency of CCOs, greatly reduced enzymatic activity without altering the dioxygenase labeling pattern. Reevaluation of the oxygen-labeling pattern of the resveratrol-cleaving CCO, NOV2, previously reported to be a monooxygenase, using a purified enzyme sample revealed that it too is a dioxygenase. We also demonstrated that bovine RPE65 is not dependent on O2 for its cleavage/isomerase activity. In conjunction with prior research, the results of this study resolve key issues regarding the utilization of O2 by CCOs and indicate that dioxygenase activity is a feature common among double bond-cleaving CCOs.

Published
2015

26. Retinylamine Benefits Early Diabetic Retinopathy in Mice*

Author

Liu, Haitao, Tang, Jie, Du, Yunpeng, Lee, Chieh Allen, Golczak, Marcin, Muthusamy, Arivalagan, Antonetti, David A, Veenstra, Alexander A, Amengual, Jaume, von Lintig, Johannes, Palczewski, Krzysztof, and Kern, Timothy S

Subjects
Biomedical and Clinical Sciences, Ophthalmology and Optometry, Eye Disease and Disorders of Vision, Neurosciences, Diabetes, Eye, Metabolic and endocrine, Acyltransferases, Animals, Cell Separation, Diabetic Retinopathy, Diterpenes, Dose-Response Relationship, Drug, Endothelial Cells, Glucose, Inflammation, Leukocytes, Male, Mice, Inbred C57BL, Oxidative Stress, Permeability, Photoreceptor Cells, Vertebrate, Retina, Superoxides, diabetes, endothelium, inflammation, reactive oxygen species, retina, hyperglycemia, retinal pigment epithelium, retinylamine, Chemical Sciences, Biological Sciences, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences
Abstract

Recent evidence suggests an important role for outer retinal cells in the pathogenesis of diabetic retinopathy (DR). Here we investigated the effect of the visual cycle inhibitor retinylamine (Ret-NH2) on the development of early DR lesions. Wild-type (WT) C57BL/6J mice (male, 2 months old when diabetes was induced) were made diabetic with streptozotocin, and some were given Ret-NH2 once per week. Lecithin-retinol acyltransferase (LRAT)-deficient mice and P23H mutant mice were similarly studied. Mice were euthanized after 2 (WT and Lrat(-/-)) and 8 months (WT) of study to assess vascular histopathology, accumulation of albumin, visual function, and biochemical and physiological abnormalities in the retina. Non-retinal effects of Ret-NH2 were examined in leukocytes treated in vivo. Superoxide generation and expression of inflammatory proteins were significantly increased in retinas of mice diabetic for 2 or 8 months, and the number of degenerate retinal capillaries and accumulation of albumin in neural retina were significantly increased in mice diabetic for 8 months compared with nondiabetic controls. Administration of Ret-NH2 once per week inhibited capillary degeneration and accumulation of albumin in the neural retina, significantly reducing diabetes-induced retinal superoxide and expression of inflammatory proteins. Superoxide generation also was suppressed in Lrat(-/-) diabetic mice. Leukocytes isolated from diabetic mice treated with Ret-NH2 caused significantly less cytotoxicity to retinal endothelial cells ex vivo than did leukocytes from control diabetics. Administration of Ret-NH2 once per week significantly inhibited the pathogenesis of lesions characteristic of early DR in diabetic mice. The visual cycle constitutes a novel target for inhibition of DR.

Published
2015

28. STRA6 is critical for cellular vitamin A uptake and homeostasis.

Author

Amengual, Jaume, Zhang, Ning, Kemerer, Mary, Maeda, Tadao, Palczewski, Krzysztof, and Von Lintig, Johannes

Subjects
Animals, Brain, Choroid Plexus, Eye, Homeostasis, Membrane Proteins, Mice, Mice, Knockout, Mutation, Protein Transport, Retinoids, Retinol-Binding Proteins, Plasma, Vitamin A, Vitamin A Deficiency
Abstract

Vitamin A must be adequately distributed within the body to maintain the functions of retinoids in the periphery and chromophore production in the eyes. Blood transport of the lipophilic vitamin is mediated by the retinol-binding protein, RBP4. Biochemical evidence suggests that cellular uptake of vitamin A from RBP4 is facilitated by a membrane receptor. This receptor, identified as the Stimulated by retinoic acid gene 6 (Stra6) gene product, is highly expressed in epithelia that constitute blood-tissue barriers. Here we established a Stra6 knockout mouse model to analyze the metabolic basis of vitamin A homeostasis in peripheral tissues. These mice were viable when bred on diets replete in vitamin A, but evidenced markedly reduced levels of ocular retinoids. Ophthalmic imaging and histology revealed malformations in the choroid and retinal pigmented epithelium, early cone photoreceptor cell death, and reduced lengths of rod outer segments. Similar to the blood-retina barrier in the RPE, vitamin A transport through the blood-cerebrospinal fluid barrier in the brains choroid plexus was impaired. Notably, treatment with pharmacological doses of vitamin A restored vitamin A transport across these barriers and rescued the vision of Stra6(-/-) mice. Furthermore, under conditions mimicking vitamin A excess and deficiency, our analyses revealed that STRA6-mediated vitamin A uptake is a regulated process mandatory for ocular vitamin A uptake when RBP4 constitutes the only transport mode in vitamin A deficiency. These findings identifying STRA6 as a bona fide vitamin A transporter have important implications for disease states associated with impaired blood vitamin A homeostasis.

Published
2014

29. Diabetes-Induced Impairment in Visual Function in Mice: Contributions of p38 MAPK, RAGE, Leukocytes, and Aldose ReductaseVisual Function in Diabetic Mice

Author

Lee, Chieh Allen, Li, Guangyuan, Patel, Mansi D, Petrash, J Mark, Benetz, Beth Ann, Veenstra, Alex, Amengual, Jaume, von Lintig, Johannes, Burant, Christopher J, Tang, Johnny, and Kern, Timothy S

Subjects
Biomedical and Clinical Sciences, Ophthalmology and Optometry, Eye Disease and Disorders of Vision, Diabetes, Autoimmune Disease, 2.1 Biological and endogenous factors, Aetiology, Metabolic and endocrine, Eye, Aldehyde Reductase, Analysis of Variance, Animals, Contrast Sensitivity, Diabetes Mellitus, Experimental, Diabetic Retinopathy, Disease Models, Animal, Leukocytes, Mice, Mice, Inbred C57BL, Psychophysics, Receptor for Advanced Glycation End Products, Receptors, Immunologic, Sensory Thresholds, Space Perception, p38 Mitogen-Activated Protein Kinases, contrast senstivity, diabetic retinopathy, spatial frequency threshold, Biological Sciences, Medical and Health Sciences, Ophthalmology & Optometry, Ophthalmology and optometry
Abstract

PurposeVisual function is impaired in diabetes, but molecular causes of this dysfunction are not clear. We assessed effects of diabetes on visual psychophysics in mice, and tested the effect of therapeutic approaches reported previously to inhibit vascular lesions of the retinopathy.MethodsWe used the optokinetic test to assess contrast sensitivity and spatial frequency threshold in diabetic C57Bl/6J mice and age-matched nondiabetic controls between 2 and 10 months of diabetes. Contributions of p38 MAP kinase (MAPK), receptor for advanced glycation end products (RAGE), leukocytes, and aldose reductase (AR) to the defect in contrast sensitivity were investigated. Cataract, a potential contributor to reductions in vision, was scored.ResultsDiabetes of 2 months' duration impaired contrast sensitivity and spatial frequency threshold in mice. The defect in contrast sensitivity persisted for at least 10 months, and cataract did not account for this impairment. Diabetic mice deficient in AR were protected significantly from development of the diabetes-induced defects in contrast sensitivity and spatial frequency threshold. In contrast, pharmacologic inhibition of p38 MAPK or RAGE, or deletion of inducible nitrous oxide synthase (iNOS) from bone marrow-derived cells did not protect the visual function in diabetes.ConclusionsDiabetes reduces spatial frequency threshold and contrast sensitivity in mice, and the mechanism leading to development of these defects involves AR. The mechanism by which AR contributes to the diabetes-induced defect in visual function can be probed by identifying which molecular abnormalities are corrected by AR deletion, but not other therapies that do not correct the defect in visual function.

Published
2014

30. Analysis of Carotenoid Isomerase Activity in a Prototypical Carotenoid Cleavage Enzyme, Apocarotenoid Oxygenase (ACO)*

Author

Sui, Xuewu, Kiser, Philip D, Che, Tao, Carey, Paul R, Golczak, Marcin, Shi, Wuxian, von Lintig, Johannes, and Palczewski, Krzysztof

Subjects
Biochemistry and Cell Biology, Chemical Sciences, Biological Sciences, Bacterial Proteins, Biocatalysis, Carotenoids, Chromatography, High Pressure Liquid, Crystallography, X-Ray, Isomerases, Kinetics, Oxygenases, Polyethylene Glycols, Retinaldehyde, Spectrum Analysis, Raman, Synechococcus, Carotene, Carotenoid, Enzyme Catalysis, Enzyme Inactivation, Enzyme Mechanisms, Enzyme Structure, Vitamin A, Medical and Health Sciences, Biochemistry & Molecular Biology, Biological sciences, Biomedical and clinical sciences, Chemical sciences
Abstract

Carotenoid cleavage enzymes (CCEs) constitute a group of evolutionarily related proteins that metabolize a variety of carotenoid and non-carotenoid substrates. Typically, these enzymes utilize a non-heme iron center to oxidatively cleave a carbon-carbon double bond of a carotenoid substrate. Some members also isomerize specific double bonds in their substrates to yield cis-apocarotenoid products. The apocarotenoid oxygenase from Synechocystis has been hypothesized to represent one such member of this latter category of CCEs. Here, we developed a novel expression and purification protocol that enabled production of soluble, native ACO in quantities sufficient for high resolution structural and spectroscopic investigation of its catalytic mechanism. High performance liquid chromatography and Raman spectroscopy revealed that ACO exclusively formed all-trans products. We also found that linear polyoxyethylene detergents previously used for ACO crystallization strongly inhibited the apocarotenoid oxygenase activity of the enzyme. We crystallized the native enzyme in the absence of apocarotenoid substrate and found electron density in the active site that was similar in appearance to the density previously attributed to a di-cis-apocarotenoid intermediate. Our results clearly demonstrated that ACO is in fact a non-isomerizing member of the CCE family. These results indicate that careful selection of detergent is critical for the success of structural studies aimed at elucidating structures of CCE-carotenoid/retinoid complexes.

Published
2014

31. Two carotenoid oxygenases contribute to mammalian provitamin A metabolism.

Author

Amengual, Jaume, Widjaja-Adhi, M, Rodriguez-Santiago, Susana, Hessel, Susanne, Golczak, Marcin, Palczewski, Krzysztof, and von Lintig, Johannes

Subjects
Carotenoid, Enzymes, Liver, Metabolism, Vitamin A, Animals, Carotenoids, Cryptoxanthins, Dioxygenases, Hep G2 Cells, Humans, Mice, Mice, Knockout, Vitamin A, Vitamin A Deficiency, Xanthophylls, beta Carotene, beta-Carotene 15, 15-Monooxygenase
Abstract

Mammalian genomes encode two provitamin A-converting enzymes as follows: the β-carotene-15,15-oxygenase (BCO1) and the β-carotene-9,10-oxygenase (BCO2). Symmetric cleavage by BCO1 yields retinoids (β-15-apocarotenoids, C20), whereas eccentric cleavage by BCO2 produces long-chain (>C20) apocarotenoids. Here, we used genetic and biochemical approaches to clarify the contribution of these enzymes to provitamin A metabolism. We subjected wild type, Bco1(-/-), Bco2(-/-), and Bco1(-/-)Bco2(-/-) double knock-out mice to a controlled diet providing β-carotene as the sole source for apocarotenoid production. This study revealed that BCO1 is critical for retinoid homeostasis. Genetic disruption of BCO1 resulted in β-carotene accumulation and vitamin A deficiency accompanied by a BCO2-dependent production of minor amounts of β-apo-10-carotenol (APO10ol). We found that APO10ol can be esterified and transported by the same proteins as vitamin A but with a lower affinity and slower reaction kinetics. In wild type mice, APO10ol was converted to retinoids by BCO1. We also show that a stepwise cleavage by BCO2 and BCO1 with APO10ol as an intermediate could provide a mechanism to tailor asymmetric carotenoids such as β-cryptoxanthin for vitamin A production. In conclusion, our study provides evidence that mammals employ both carotenoid oxygenases to synthesize retinoids from provitamin A carotenoids.

Published
2013

34. Mutations in the Spliceosome Component CWC27 Cause Retinal Degeneration with or without Additional Developmental Anomalies

Author

Black, Graeme, Hall, Georgina, Gillespie, Rachel, Ramsden, Simon, Manson, Forbes, Sergouniotis, Panagiotis, Inglehearn, Chris, Toomes, Carmel, Ali, Manir, McKibbin, Martin, Poulter, James, Lord, Emma, Nemeth, Andrea, Halford, Stephanie, Downes, Susan, Yu, Jing, Xu, Mingchu, Xie, Yajing (Angela), Abouzeid, Hana, Gordon, Christopher T., Fiorentino, Alessia, Sun, Zixi, Lehman, Anna, Osman, Ihab S., Dharmat, Rachayata, Riveiro-Alvarez, Rosa, Bapst-Wicht, Linda, Babino, Darwin, Arno, Gavin, Busetto, Virginia, Zhao, Li, Li, Hui, Lopez-Martinez, Miguel A., Azevedo, Liliana F., Hubert, Laurence, Pontikos, Nikolas, Eblimit, Aiden, Lorda-Sanchez, Isabel, Kheir, Valeria, Plagnol, Vincent, Oufadem, Myriam, Soens, Zachry T., Yang, Lizhu, Bole-Feysot, Christine, Pfundt, Rolph, Allaman-Pillet, Nathalie, Nitschké, Patrick, Cheetham, Michael E., Lyonnet, Stanislas, Agrawal, Smriti A., Li, Huajin, Pinton, Gaëtan, Michaelides, Michel, Besmond, Claude, Li, Yumei, Yuan, Zhisheng, von Lintig, Johannes, Webster, Andrew R., Le Hir, Hervé, Stoilov, Peter, Amiel, Jeanne, Hardcastle, Alison J., Ayuso, Carmen, Sui, Ruifang, Chen, Rui, Allikmets, Rando, and Schorderet, Daniel F.

Published
2017
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39. Paracardial fat remodeling affects systemic metabolism through alcohol dehydrogenase 1

Author

Petrosino, Jennifer M., Longenecker, Jacob Z., Ramkumar, Srinivasagan, Xu, Xianyao, Dorn, Lisa E., Bratasz, Anna, Yu, Lianbo, Maurya, Santosh, Tolstikov, Vladimir, Bussberg, Valerie, Janssen, Paul M.L., Periasamy, Muthu, Kiebish, Michael A., Duester, Gregg, von Lintig, Johannes, Ziouzenkova, Ouliana, and Accornero, Federica

Subjects
Care and treatment, Genetic aspects, Health aspects, Elderly patients -- Care and treatment, Oxidoreductases -- Health aspects, Cell metabolism -- Genetic aspects -- Health aspects, Pericardium -- Genetic aspects -- Health aspects, Gene expression -- Health aspects, Aged patients -- Care and treatment
Abstract

Introduction Adipose tissue is known as both a storage and secretory organ capable of influencing local and global metabolism (reviewed in refs. 1,2) In particular, white adipose tissue acts as [...], The relationship between adiposity and metabolic health is well established. However, very little is known about the fat depot, known as paracardial fat (pCF), located superior to and surrounding the heart. Here, we show that pCF remodels with aging and a high-fat diet and that the size and function of this depot are controlled by alcohol dehydrogenase 1 (ADH1), an enzyme that oxidizes retinol into retinaldehyde. Elderly individuals and individuals with obesity have low ADH1 expression in pCF, and in mice, genetic ablation of Adh1 is sufficient to drive pCF accumulation, dysfunction, and global impairments in metabolic flexibility. Metabolomics analysis revealed that pCF controlled the levels of circulating metabolites affecting fatty acid biosynthesis. Also, surgical removal of the pCF depot was sufficient to rescue the impairments in cardiometabolic flexibility and fitness observed in Adhl-deficient mice. Furthermore, treatment with retinaldehyde prevented pCF remodeling in these animals. Mechanistically, we found that the ADH1/retinaldehyde pathway works by driving PGC-1[alpha] nuclear translocation and promoting mitochondrial fusion and biogenesis in the pCF depot. Together, these data demonstrate that pCF is a critical regulator of cardiometabolic fitness and that retinaldehyde and its generating enzyme ADH1 act as critical regulators of adipocyte remodeling in the pCF depot.

Published
2021
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