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5. Contributors

Author

Abete, Itziar, primary, Agirre, Xabier, additional, Ahlgren, Jennie, additional, Alkorta-Aranburu, Gorka, additional, Aller, Rocío, additional, Andres-Lacueva, Cristina, additional, Antonio de Luis, Daniel, additional, Babino, Darwin, additional, Bar-El Dadon, Shimrit, additional, Bonet, Maria Luisa, additional, Bordoni, Laura, additional, Borel, Patrick, additional, Bosch, Annet M., additional, Brown, Steven, additional, Busso, Dolores, additional, Calabriso, Nadia, additional, Capurso, Antonio, additional, Capurso, Cristiano, additional, Cariello, Marica, additional, Carluccio, Maria Annunziata, additional, Casas-Agustench, Patricia, additional, Cheatham, Carol L., additional, Chirita-Emandi, Adela, additional, Chittoor, Geetha, additional, Choi, Myung-Sook, additional, Choi, Sang-Woon, additional, Cordero, Paul, additional, Corrales, Fernando J., additional, Cortés, Víctor, additional, Cross, Nicholas C.P., additional, Crujeiras, Ana B., additional, Curi, Rui, additional, De Caterina, Raffaele, additional, de Lorenzo, David, additional, Desmarchelier, Charles, additional, Dong, Olivia, additional, Estruch, Ramón, additional, Ezponda, Teresa, additional, Fenech, Michael, additional, Ferguson, Lynnette R., additional, Fischer, Karina, additional, Fontana, Luigi, additional, Friso, Simonetta, additional, Gabbianelli, Rosita, additional, Garaulet, Marat, additional, Garcia-Irigoyen, Oihane, additional, Gil, Angel, additional, Gómez-Abellán, Purificación, additional, Görman, Ulf, additional, Harris, William S., additional, Hernandez-Vazquez, Alain de J., additional, Hugenholtz, Paul, additional, Hyde, Lara K., additional, Ibáñez, Clara, additional, Izaola, Olatz, additional, Jones, Peter J.H., additional, Kirwan, Richard, additional, Kohlmeier, Martin, additional, Krupenko, Natalia I., additional, Kwon, Eun-Young, additional, Lamming, Dudley W., additional, Lamuela-Raventos, Rosa M., additional, Langin, Dominique, additional, Langley-Evans, Simon, additional, Lira do Amaral, Cátia, additional, Lopez-Minguez, Jesus, additional, Madonna, Rosalinda, additional, Mansego, Maria L., additional, Marotz, Clarisse, additional, Martinez, J. Alfredo, additional, Massaro, Marika, additional, McRitchie, Susan, additional, Mesmar, Bayan, additional, Milagro, Fermín I., additional, Moreno-Aliaga, María J., additional, Moreno-Indias, Isabel, additional, Moschetta, Antonio, additional, Navas-Carretero, Santiago, additional, Niculescu, Mihai, additional, Nordström, Karin, additional, Novo, Francisco J., additional, Oben, Jude A., additional, Odriozola, Leticia, additional, Ordovas, Jose M., additional, Palou, Andreu, additional, Parslow, Virginia R., additional, Pathmasiri, Wimal, additional, Pérez-Castrillón, José Luis, additional, Pérusse, Louis, additional, Piccinin, Elena, additional, Plaza-Diaz, Julio, additional, Prósper, Felipe, additional, Qi, Lu, additional, Ralston, Jessica C., additional, Ramírez de Molina, Ana, additional, Rasti, George, additional, Reifen, Ram, additional, Renda, Giulia, additional, Riancho, José A., additional, Riancho del Moral, José Antonio, additional, Rivadeneira, Fernando, additional, Roche, Helen M., additional, Ruiz-Mambrilla, Marta, additional, Ruiz-Ojeda, Francisco Javier, additional, Salas-Pérez, Francisca, additional, San-Cristobal, Rodrigo, additional, Santander, Nicolás, additional, Santos, José L., additional, Saupe, Jörg, additional, Scoditti, Egeria, additional, Serhan, Charles N., additional, Simonet, Nicolas G., additional, Simopoulos, Artemis P., additional, Steinle, Nanette, additional, Sumner, Susan C.J., additional, Tinahones, Francisco J., additional, Vaquero, Alejandro, additional, Vazquez-Vidal, Itzel, additional, Velazquez-Arellano, Antonio, additional, Viguerie, Nathalie, additional, Vinciguerra, Manlio, additional, Visioli, Francesco, additional, Vizmanos, José L., additional, von Lintig, Johannes, additional, Voruganti, Venkata Saroja, additional, Wanders, Ronald J.A., additional, Wang, Tiange, additional, Wiltshire, Tim, additional, Yu, Deyang, additional, Zarrinpar, Amir, additional, Zeisel, Steven H., additional, and Zulet, Maria Angeles, additional

Published
2020
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6. Contributors to Volume 1

Author

Aggett, Peter J., primary, Ahnen, Rylee T., additional, Aydemir, Tolunay Beker, additional, Bailey, Lynn B., additional, Bettendorff, Lucien, additional, Blaner, William S., additional, Borum, Peggy R., additional, Bruno, Richard S., additional, Calder, Philip C., additional, Caudill, Marie A., additional, Cheuvront, Samuel N., additional, Coates, Paul M., additional, Collins, James F., additional, Costello, Rebecca B., additional, da Silva, Vanessa R., additional, Diamond, Alan Mark, additional, Ferland, Guylaine, additional, Fleet, James C., additional, Fukagawa, Naomi K., additional, Gregory, Jesse F., additional, Gutiérrez, Orlando M., additional, Haggans, Carol J., additional, Hong, Lenny K., additional, Johnson, Ian T., additional, Johnston, Carol S., additional, Jones, Peter J.H., additional, Kenefick, Robert W., additional, Kirkland, James B., additional, Leone, Vanessa A., additional, Lichtenstein, Alice H., additional, Mc Auley, Mark Tomás, additional, McCormick, Donald B., additional, Merrill, Alfred H., additional, Miller, Joshua W., additional, Montain, Scott J., additional, Mottet, Rachel, additional, Nielsen, Forrest H., additional, Omolo, Morrine, additional, Penberthy, William Todd, additional, Pierre, Joseph F., additional, Preuss, Harry G., additional, Rosanoff, A., additional, Rucker, Robert B., additional, Ryu, Moon-Suhn, additional, Sadri, Mahrou, additional, Sawka, Michael N., additional, Shapses, Sue A., additional, Slavin, Joanne, additional, Stabler, Sally P., additional, Thomas, Paul R., additional, Traber, Maret G., additional, Trujillo-Gonzalez, Isis, additional, Vincent, John B., additional, von Lintig, Johannes, additional, Weaver, Connie M., additional, West, Allyson A., additional, Westerterp, Klaas R., additional, Williamson, Gary, additional, Yaqoob, Parveen, additional, Yu, Yong-Ming, additional, Zeisel, Steven H., additional, Zempleni, Janos, additional, and Zimmermann, Michael B., additional

Published
2020
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8. ASTER-B regulates mitochondrial carotenoid transport and homeostasis.

Author

Bandara S, Moon J, Ramkumar S, and von Lintig J

Subjects
Animals, Humans, Zeaxanthins metabolism, Cholesterol, Mitochondria metabolism, Homeostasis, Mammals metabolism, Carotenoids metabolism, beta Carotene metabolism
Abstract

The scavenger receptor class B type 1 (SR-B1) facilitates uptake of cholesterol and carotenoids into the plasma membrane (PM) of mammalian cells. Downstream of SR-B1, ASTER-B protein mediates the nonvesicular transport of cholesterol to mitochondria for steroidogenesis. Mitochondria also are the place for the processing of carotenoids into diapocarotenoids by β-carotene oxygenase-2. However, the role of these lipid transport proteins in carotenoid metabolism has not yet been established. Herein, we showed that the recombinant StART-like lipid-binding domain of ASTER-A and B preferentially binds oxygenated carotenoids such as zeaxanthin. We established a novel carotenoid uptake assay and demonstrated that ASTER-B expressing A549 cells transport zeaxanthin to mitochondria. In contrast, the pure hydrocarbon β-carotene is not transported to the organelles, consistent with its metabolic processing to vitamin A in the cytosol by β-carotene oxygenase-1. Depletion of the PM from cholesterol by methyl-β-cyclodextrin treatment enhanced zeaxanthin but not β-carotene transport to mitochondria. Loss-of-function assays by siRNA in A549 cells and the absence of zeaxanthin accumulation in mitochondria of ARPE19 cells confirmed the pivotal role of ASTER-B in this process. Together, our study in human cell lines established ASTER-B protein as key player in nonvesicular transport of zeaxanthin to mitochondria and elucidated the molecular basis of compartmentalization of the metabolism of nonprovitamin A and provitamin A carotenoids in mammalian cells., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2023 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2023
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9. Genetic dissection in mice reveals a dynamic crosstalk between the delivery pathways of vitamin A.

Author

Moon J, Ramkumar S, and von Lintig J

Subjects
Animals, Homeostasis, Mice, Retinoids metabolism, Retinol-Binding Proteins genetics, Retinol-Binding Proteins metabolism, Provitamins, Vitamin A metabolism
Abstract

Vitamin A is distributed within the body to support chromophore synthesis in the eyes and retinoid signaling in most other tissues. Two pathways exist for the delivery of vitamin A: the extrinsic pathway transports dietary vitamin A in lipoproteins from intestinal enterocytes to tissues, while the intrinsic pathway distributes vitamin A from hepatic stores bound to serum retinol binding protein (RBP). Previously, the intestine-specific homeodomain transcription factor (ISX) and the RBP receptor STRA6 were identified as gatekeepers of these pathways; however, it is not clear how mutations in the corresponding genes affect retinoid homeostasis. Here, we used a genetic dissection approach in mice to examine the contributions of these proteins in select tissues. We observed that ISX deficiency increased utilization of both preformed and provitamin A. We found that increased storage of retinoids in peripheral tissues of ISX-deficient mice was dependent on STRA6 and induced by retinoid signaling. In addition, double-mutant mice exhibited a partial rescue of the Stra6 mutant ocular phenotype. This rescue came at the expense of a massive accumulation of vitamin A in other tissues, demonstrating that vitamin A is randomly distributed when present in excessive amounts. Remarkably, provitamin A supplementation of mutant mice induced the expression of the RBP receptor 2 in the liver and was accompanied by increased hepatic retinyl ester stores. Taken together, these findings indicate dynamic crosstalk between the delivery pathways for this essential nutrient and suggest that hepatic reuptake of vitamin A takes place when excessive amounts circulate in the blood., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2022 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2022
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10. LRAT coordinates the negative-feedback regulation of intestinal retinoid biosynthesis from β-carotene.

Author

Ramkumar S, Moon J, Golczak M, and von Lintig J

Subjects
Animals, Mice, Homeodomain Proteins metabolism, Homeodomain Proteins genetics, Vitamin A metabolism, Vitamin A biosynthesis, Intestinal Mucosa metabolism, Intestines, Transcription Factors, Retinoids metabolism, beta Carotene metabolism, Feedback, Physiological, Acyltransferases metabolism, Acyltransferases genetics
Abstract

There is increasing recognition that dietary lipids can affect the expression of genes encoding their metabolizing enzymes, transporters, and binding proteins. This mechanism plays a pivotal role in controlling tissue homeostasis of these compounds and avoiding diseases. The regulation of retinoid biosynthesis from β-carotene (BC) is a classic example for such an interaction. The intestine-specific homeodomain transcription factor (ISX) controls the activity of the vitamin A-forming enzyme β-carotene oxygenase-1 in intestinal enterocytes in response to increasing concentration of the vitamin A metabolite retinoic acid. However, it is unclear how cells control the concentration of the signaling molecule in this negative-feedback loop. We demonstrate in mice that the sequestration of retinyl esters by the enzyme lecithin:retinol acyltransferase (LRAT) is central for this process. Using genetic and pharmacological approaches in mice, we observed that in LRAT deficiency, the transcription factor ISX became hypersensitive to dietary vitamin A and suppressed retinoid biosynthesis. The dysregulation of the pathway resulted in BC accumulation and vitamin A deficiency of extrahepatic tissues. Pharmacological inhibition of retinoid signaling and genetic depletion of the Isx gene restored retinoid biosynthesis in enterocytes. We provide evidence that the catalytic activity of LRAT coordinates the negative-feedback regulation of intestinal retinoid biosynthesis and maintains optimal retinoid levels in the body., Competing Interests: Conflict of interest The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2021 The Authors. Published by Elsevier Inc. All rights reserved.)

Published
2021
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11. Overlapping Vitamin A Interventions with Provitamin A Carotenoids and Preformed Vitamin A Cause Excessive Liver Retinol Stores in Male Mongolian Gerbils.

Author

Sowa M, Mourao L, Sheftel J, Kaeppler M, Simons G, Grahn M, Davis CR, von Lintig J, Simon PW, Pixley KV, and Tanumihardjo SA

Subjects
Animal Feed, Animals, Biofortification, Carotenoids adverse effects, Carotenoids metabolism, Daucus carota, Dose-Response Relationship, Drug, Drug Interactions, Gerbillinae, Liver metabolism, Male, Vitamin A adverse effects, Zea mays, Carotenoids administration & dosage, Carotenoids pharmacokinetics, Liver chemistry, Vitamin A administration & dosage, Vitamin A pharmacokinetics
Abstract

Background: Vitamin A (VA) deficiency is a public health problem in some countries. Fortification, supplementation, and increased provitamin A consumption through biofortification are efficacious, but monitoring is needed due to risk of excessive VA intake when interventions overlap., Objectives: Two studies in 28-36-d-old male Mongolian gerbils simulated exposure to multiple VA interventions to determine the effects of provitamin A carotenoid consumption from biofortified maize and carrots and preformed VA fortificant on status., Methods: Study 1 was a 2 × 2 × 2 factorial design (n = 85) with high-β-carotene maize, orange carrots, and VA fortification at 50% estimated gerbil needs, compared with white maize and white carrot controls. Study 2 was a 2 × 3 factorial design (n = 66) evaluating orange carrot and VA consumption through fortification at 100% and 200% estimated needs. Both studies utilized 2-wk VA depletion, baseline evaluation, 9-wk treatments, and liver VA stores by HPLC. Intestinal scavenger receptor class B member 1 (Scarb1), β-carotene 15,15'-dioxygenase (Bco1), β-carotene 9',10'-oxygenase (Bco2), intestine-specific homeobox (Isx), and cytochrome P450 26A1 isoform α1 (Cyp26a1) expression was analyzed by qRT-PCR in study 2., Results: In study 1, liver VA concentrations were significantly higher in orange carrot (0.69 ± 0.12 μmol/g) and orange maize groups (0.52 ± 0.21 μmol/g) compared with baseline (0.23 ± 0.069 μmol/g) and controls. Liver VA concentrations from VA fortificant alone (0.11 ± 0.053 μmol/g) did not differ from negative control. In study 2, orange carrot significantly enhanced liver VA concentrations (0.85 ± 0.24 μmol/g) relative to baseline (0.43 ± 0.14 μmol/g), but VA fortificant alone (0.42 ± 0.21 μmol/g) did not. Intestinal Scarb1 and Bco1 were negatively correlated with increasing liver VA concentrations (P < 0.01, r2 = 0.25-0.27). Serum retinol concentrations did not differ., Conclusions: Biofortified carrots and maize without fortification prevented VA deficiency in gerbils. During adequate provitamin A dietary intake, preformed VA intake resulted in excessive liver stores in gerbils, despite downregulation of carotenoid absorption and cleavage gene expression., (Copyright © The Author(s) on behalf of the American Society for Nutrition 2020.)

Published
2020
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13. β-Carotene conversion to vitamin A delays atherosclerosis progression by decreasing hepatic lipid secretion in mice.

Author

Zhou F, Wu X, Pinos I, Abraham BM, Barrett TJ, von Lintig J, Fisher EA, and Amengual J

Subjects
Animals, Atherosclerosis pathology, Cells, Cultured, Female, Lipid Metabolism, Liver metabolism, Male, Mice, Mice, Inbred C57BL, Mice, Knockout, Receptors, LDL deficiency, Receptors, LDL metabolism, beta-Carotene 15,15'-Monooxygenase deficiency, beta-Carotene 15,15'-Monooxygenase metabolism, Atherosclerosis metabolism, Lipids chemistry, Liver chemistry, Vitamin A metabolism, beta Carotene metabolism
Abstract

Atherosclerosis is characterized by the pathological accumulation of cholesterol-laden macrophages in the arterial wall. Atherosclerosis is also the main underlying cause of CVDs, and its development is largely driven by elevated plasma cholesterol. Strong epidemiological data find an inverse association between plasma β-carotene with atherosclerosis, and we recently showed that β-carotene oxygenase 1 (BCO1) activity, responsible for β-carotene cleavage to vitamin A, is associated with reduced plasma cholesterol in humans and mice. In this study, we explore whether intact β-carotene or vitamin A affects atherosclerosis progression in the atheroprone LDLR-deficient mice. Compared with control-fed Ldlr -/- mice, β-carotene-supplemented mice showed reduced atherosclerotic lesion size at the level of the aortic root and reduced plasma cholesterol levels. These changes were absent in Ldlr -/- / Bco1 -/- mice despite accumulating β-carotene in plasma and atherosclerotic lesions. We discarded the implication of myeloid BCO1 in the development of atherosclerosis by performing bone marrow transplant experiments. Lipid production assays found that retinoic acid, the active form of vitamin A, reduced the secretion of newly synthetized triglyceride and cholesteryl ester in cell culture and mice. Overall, our findings provide insights into the role of BCO1 activity and vitamin A in atherosclerosis progression through the regulation of hepatic lipid metabolism., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (Copyright © 2020 Zhou et al.)

Published
2020
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14. Carotenoid metabolism at the intestinal barrier.

Author

von Lintig J, Moon J, Lee J, and Ramkumar S

Subjects
Animals, Homeostasis, Humans, Intestinal Absorption genetics, Lipid Metabolism genetics, Triglycerides metabolism, Vitamin A genetics, Carotenoids metabolism, Lipids genetics, Liver metabolism, Vitamin A metabolism
Abstract

Carotenoids exert a rich variety of physiological functions in mammals and are beneficial for human health. These lipids are acquired from the diet and metabolized to apocarotenoids, including retinoids (vitamin A and its metabolites). The small intestine is a major site for their absorption and bioconversion. From here, carotenoids and their metabolites are distributed within the body in triacylglycerol-rich lipoproteins to support retinoid signaling in peripheral tissues and photoreceptor function in the eyes. In recent years, much progress has been made in identifying carotenoid metabolizing enzymes, transporters, and binding proteins. A diet-responsive regulatory network controls the activity of these components and adapts carotenoid absorption and bioconversion to the bodily requirements of these lipids. Genetic variability in the genes encoding these components alters carotenoid homeostasis and is associated with pathologies. We here summarize the advanced state of knowledge about intestinal carotenoid metabolism and its impact on carotenoid and retinoid homeostasis of other organ systems, including the eyes, liver, and immune system. The implication of the findings for science-based intake recommendations for these essential dietary lipids is discussed. This article is part of a Special Issue entitled Carotenoids recent advances in cell and molecular biology edited by Johannes von Lintig and Loredana Quadro., Competing Interests: Declaration of competing interest The authors declare no conflict of interest., (Copyright © 2019. Published by Elsevier B.V.)

Published
2020
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15. Astaxanthin-Shifted Gut Microbiota Is Associated with Inflammation and Metabolic Homeostasis in Mice.

Author

Wu L, Lyu Y, Srinivasagan R, Wu J, Ojo B, Tang M, El-Rassi GD, Metzinger K, Smith BJ, Lucas EA, Clarke SL, Chowanadisai W, Shen X, He H, Conway T, von Lintig J, and Lin D

Subjects
Animal Feed analysis, Animals, Bacteria classification, Bacteria drug effects, Diet veterinary, Dietary Supplements, Dioxygenases genetics, Dioxygenases metabolism, Female, Homeostasis drug effects, Male, Mice, Mice, Knockout, Xanthophylls administration & dosage, Xanthophylls pharmacology, Energy Metabolism drug effects, Gastrointestinal Microbiome drug effects, Inflammation drug therapy
Abstract

Background: Astaxanthin is a red lipophilic carotenoid that is often undetectable in human plasma due to the limited supply in typical Western diets. Despite its presence at lower than detectable concentrations, previous clinical feeding studies have reported that astaxanthin exhibits potent antioxidant properties., Objective: We examined astaxanthin accumulation and its effects on gut microbiota, inflammation, and whole-body metabolic homeostasis in wild-type C57BL/6 J (WT) and β-carotene oxygenase 2 (BCO2) knockout (KO) mice., Methods: Six-wk-old male and female BCO2 KO and WT mice were provided with either nonpurified AIN93M (e.g., control diet) or the control diet supplemented with 0.04% astaxanthin (wt/wt) ad libitum for 8 wk. Whole-body energy expenditure was measured by indirect calorimetry. Feces were collected from individual mice for short-chain fatty acid assessment. Hepatic astaxanthin concentrations and liver metabolic markers, cecal gut microbiota profiling, inflammation markers in colonic lamina propria, and plasma samples were assessed. Data were analyzed by 3-way ANOVA followed by Tukey's post hoc analysis., Results: BCO2 KO but not WT mice fed astaxanthin had ∼10-fold more of this compound in liver than controls (P < 0.05). In terms of the microbiota composition, deletion of BCO2 was associated with a significantly increased abundance of Mucispirillum schaedleri in mice regardless of gender. In addition to more liver astaxanthin in male KO compared with WT mice fed astaxanthin, the abundance of gut Akkermansia muciniphila was 385% greater, plasma glucagon-like peptide 1 was 27% greater, plasma glucagon and IL-1β were 53% and 30% lower, respectively, and colon NOD-, LRR- and pyrin domain-containing protein 3 (NLRP3) inflammasome activation was 23% lower (all P < 0.05) in male KO mice than the WT mice., Conclusions: Astaxanthin affects the gut microbiota composition in both genders, but the association with reductions in local and systemic inflammation, oxidative stress, and improvement of metabolic homeostasis only occurs in male mice., (Copyright © The Author(s) on behalf of the American Society for Nutrition 2020.)

Published
2020
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18. Genetic dissection in a mouse model reveals interactions between carotenoids and lipid metabolism.

Author

Palczewski G, Widjaja-Adhi MA, Amengual J, Golczak M, and von Lintig J

Subjects
Animals, Cholesterol genetics, Diet, Disease Models, Animal, Energy Metabolism genetics, Humans, Lipids genetics, Lipolysis genetics, Liver drug effects, Liver metabolism, Lutein administration & dosage, Lutein blood, Metabolism genetics, Mice, Triglycerides blood, Triglycerides genetics, Zeaxanthins administration & dosage, beta Carotene administration & dosage, beta Carotene blood, Carotenoids metabolism, Cholesterol blood, Lipid Metabolism, Lipids blood, Transcriptome genetics
Abstract

Carotenoids affect a rich variety of physiological functions in nature and are beneficial for human health. However, knowledge about their biological action and the consequences of their dietary accumulation in mammals is limited. Progress in this research field is limited by the expeditious metabolism of carotenoids in rodents and the confounding production of apocarotenoid signaling molecules. Herein, we established a mouse model lacking the enzymes responsible for carotenoid catabolism and apocarotenoid production, fed on either a β-carotene- or a zeaxanthin-enriched diet. Applying a genome wide microarray analysis, we assessed the effects of the parent carotenoids on the liver transcriptome. Our analysis documented changes in pathways for liver lipid metabolism and mitochondrial respiration. We biochemically defined these effects, and observed that β-carotene accumulation resulted in an elevation of liver triglycerides and liver cholesterol, while zeaxanthin accumulation increased serum cholesterol levels. We further show that carotenoids were predominantly transported within HDL particles in the serum of mice. Finally, we provide evidence that carotenoid accumulation influenced whole-body respiration and energy expenditure. Thus, we observed that accumulation of parent carotenoids interacts with lipid metabolism and that structurally related carotenoids display distinct biological functions in mammals., (Copyright © 2016 by the American Society for Biochemistry and Molecular Biology, Inc.)

Published
2016
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19. Lycopene and apo-10'-lycopenoic acid have differential mechanisms of protection against hepatic steatosis in β-carotene-9',10'-oxygenase knockout male mice.

Author

Ip BC, Liu C, Lichtenstein AH, von Lintig J, and Wang XD

Subjects
AMP-Activated Protein Kinases genetics, AMP-Activated Protein Kinases metabolism, ATP-Binding Cassette Transporters genetics, ATP-Binding Cassette Transporters metabolism, Acetyl-CoA Carboxylase metabolism, Adipose Tissue drug effects, Adipose Tissue metabolism, Animals, Biomarkers blood, Carotenoids administration & dosage, Cholesterol blood, Diet, High-Fat, Dioxygenases metabolism, Fatty Acids administration & dosage, Fatty Acids adverse effects, Fatty Acids, Unsaturated administration & dosage, Female, Forkhead Box Protein O1, Forkhead Transcription Factors genetics, Forkhead Transcription Factors metabolism, Liver drug effects, Liver metabolism, Lycopene, Male, Mice, Mice, Knockout, PPAR alpha genetics, PPAR alpha metabolism, PPAR gamma genetics, PPAR gamma metabolism, Phosphorylation, Signal Transduction, Sirtuin 1 genetics, Sirtuin 1 metabolism, Stearoyl-CoA Desaturase genetics, Stearoyl-CoA Desaturase metabolism, Triglycerides blood, Up-Regulation, Carotenoids blood, Dioxygenases genetics, Fatty Acids, Unsaturated blood, Fatty Liver drug therapy
Abstract

Background: Nonalcoholic fatty liver disease is positively associated with obesity and cardiovascular disease risk. Apo-10'-lycopenoic acid (APO10LA), a potential oxidation product of apo-10'-lycopenal that is generated endogenously by β-carotene-9',10'-oxygenase (BCO2) cleavage of lycopene, inhibited hepatic steatosis in BCO2-expressing mice., Objective: The present study evaluated lycopene and APO10LA effects on hepatic steatosis in mice without BCO2 expression., Methods: Male and female BCO2-knockout (BCO2-KO) mice were fed a high saturated fat diet (HSFD) with or without APO10LA (10 mg/kg diet) or lycopene (100 mg/kg diet) for 12 wk., Results: Lycopene or APO10LA supplementation reduced hepatic steatosis incidence (78% and 72%, respectively) and severity in BCO2-KO male mice. Female mice did not develop steatosis, had greater hepatic total cholesterol (3.06 vs. 2.31 mg/g tissue) and cholesteryl ester (1.58 vs. 0.86 mg/g tissue), but had lower plasma triglyceride (TG) (229 vs. 282 mg/dL) and cholesterol (97.1 vs. 119 mg/dL) than male mice. APO10LA-mitigated steatosis in males was associated with reduced hepatic total cholesterol (18%) and activated sirtuin 1 signaling, which resulted in reduced fatty acids (FAs) and TG synthesis markers [stearoyl-coenzyme A (CoA) desaturase protein, 71%; acetyl-CoA carboxylase phosphorylation, 79%; AMP-activated protein kinase phosphorylation, 67%], and elevated cholesterol efflux genes (cytochrome P450 family 7A1, 65%; ATP-binding cassette transporter G5/8, 11%). These APO10LA-mediated effects were not mimicked by lycopene supplementation. Intriguingly, steatosis inhibition by lycopene induced peroxisome proliferator-activated receptor (PPAR)α- and PPARγ-related genes in mesenteric adipose tissue (MAT) that increases mitochondrial uncoupling [cell death-inducing DNA fragmentation factor, α subunit-like effector a, 55%; PR domain-containing 16, 47%; uncoupling protein 3 (Ucp3), 55%], FA β-oxidation (PPARα, 53%; very long chain acyl-CoA dehydrogenase, 38%), and uptake (FA transport protein 4, 29%; lipoprotein lipase 43%). Expressions of 10 MAT PPAR-related genes were inversely correlated with steatosis score, suggesting that lycopene reduced steatosis by increasing MAT FA utilization., Conclusions: Our data suggest that lycopene and APO10LA inhibit HSFD-induced steatosis in BCO2-KO male mice through differential mechanisms. Sex disparity of BCO2-KO mice was observed in the outcomes of HSFD-induced liver steatosis and plasma lipids., (© 2015 American Society for Nutrition.)

Published
2015
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20. Carotenoids.

Author

von Lintig J and Sies H

Subjects
Animals, Carotenoids biosynthesis, Carotenoids physiology, Humans, Internationality, Light, Plants chemistry, Seasons, Carotenoids chemistry
Published
2013
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21. Characterization of human β,β-carotene-15,15'-monooxygenase (BCMO1) as a soluble monomeric enzyme.

Author

Kowatz T, Babino D, Kiser P, Palczewski K, and von Lintig J

Subjects
Animals, Cell Line, Gene Expression Regulation, Enzymologic, Humans, Liver enzymology, Mice, Recombinant Proteins isolation & purification, Retinaldehyde chemistry, Solubility, Spodoptera enzymology, Substrate Specificity genetics, Transfection, Vitamin A chemistry, Vitamin A metabolism, beta-Carotene 15,15'-Monooxygenase genetics, beta-Carotene 15,15'-Monooxygenase isolation & purification, beta-Carotene 15,15'-Monooxygenase chemistry
Abstract

The formal first step in in vitamin A metabolism is the conversion of its natural precursor β,β-carotene (C40) to retinaldehyde (C20). This reaction is catalyzed by the enzyme β,β-carotene-15,15'-monooxygenase (BCMO1). BCMO1 has been cloned from several vertebrate species, including humans. However, knowledge about this protein's enzymatic and structural properties is scant. Here we expressed human BCMO1 in Spodoptera frugiperda 9 insect cells. Recombinant BCMO1 is a soluble protein that displayed Michaelis-Menten kinetics with a KM of 14 μM for β,β-carotene. Though addition of detergents failed to increase BCMO1 enzymatic activity, short chain aliphatic detergents such as C8E4 and C8E6 decreased enzymatic activity probably by interacting with the substrate binding site. Thus we purified BCMO1 in the absence of detergent. Purified BCMO1 was a monomeric enzymatically active soluble protein that did not require cofactors and displayed a turnover rate of about 8 molecules of β,β-carotene per second. The aqueous solubility of BCMO1 was confirmed in mouse liver and mammalian cells. Establishment of a protocol that yields highly active homogenous BCMO1 is an important step towards clarifying the lipophilic substrate interaction, reaction mechanism and structure of this vitamin A forming enzyme., (Copyright © 2013 Elsevier Inc. All rights reserved.)

Published
2013
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22. Provitamin A metabolism and functions in mammalian biology.

Author

von Lintig J

Subjects
Animals, Dioxygenases biosynthesis, Dioxygenases genetics, Gene Expression Regulation, Humans, Intestinal Absorption, Mice, Vitamin A genetics, Vitamin A pharmacokinetics, Vitamin A Deficiency prevention & control, beta Carotene pharmacokinetics, beta-Carotene 15,15'-Monooxygenase biosynthesis, beta-Carotene 15,15'-Monooxygenase genetics, Vitamin A metabolism, Vitamin A pharmacology, Vitamin A Deficiency metabolism, beta Carotene metabolism
Abstract

Vitamin A deficiency is a major public health problem in developing countries. Some studies also implicate a suboptimal vitamin A intake in certain parts of the population of the industrialized world. Provitamin A carotenoids such as β-carotene are the major source for retinoids (vitamin A and its derivatives) in the human diet. However, it is still controversial how much β-carotene intake is required and safe. An important contributor to this uncertainty is the lack of knowledge about the biochemical and molecular basis of β-carotene metabolism. Recently, key players of provitamin A metabolism have been molecularly identified and biochemically characterized. Studies in knockout mouse models showed that intestinal β-carotene absorption and conversion to retinoids is under negative feedback regulation that adapts this process to the actual requirement of vitamin A of the body. These studies also showed that in peripheral tissues a conversion of β-carotene occurs and affects retinoid-dependent physiologic processes. Moreover, these analyses provided a possible explanation for the adverse health effects of carotenoids by showing that a pathologic accumulation of these compounds can induce oxidative stress in mitochondria and cell signaling pathways related to disease. Genetic polymorphisms in identified genes exist in humans and also alter carotenoid homeostasis. Here, the advanced knowledge of β-carotene metabolism is reviewed, which provides a molecular framework for understanding the role of this important micronutrient in health and disease.

Published
2012
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23. Hepatic stellate cells are an important cellular site for β-carotene conversion to retinoid.

Author

Shmarakov I, Fleshman MK, D'Ambrosio DN, Piantedosi R, Riedl KM, Schwartz SJ, Curley RW Jr, von Lintig J, Rubin LP, Harrison EH, and Blaner WS

Subjects
Animals, Female, Gene Expression Regulation, Enzymologic, Hepatocytes metabolism, Male, Mice, RNA, Messenger genetics, RNA, Messenger metabolism, beta-Carotene 15,15'-Monooxygenase deficiency, beta-Carotene 15,15'-Monooxygenase genetics, beta-Carotene 15,15'-Monooxygenase metabolism, Hepatic Stellate Cells metabolism, Retinoids metabolism, beta Carotene metabolism
Abstract

Hepatic stellate cells (HSCs) are responsible for storing 90-95% of the retinoid present in the liver. These cells have been reported in the literature also to accumulate dietary β-carotene, but the ability of HSCs to metabolize β-carotene in situ has not been explored. To gain understanding of this, we investigated whether β-carotene-15,15'-monooxygenase (Bcmo1) and β-carotene-9',10'-monooxygenase (Bcmo2) are expressed in HSCs. Using primary HSCs and hepatocytes purified from wild type and Bcmo1-deficient mice, we establish that Bcmo1 is highly expressed in HSCs; whereas Bcmo2 is expressed primarily in hepatocytes. We also confirmed that HSCs are an important cellular site within the liver for accumulation of dietary β-carotene. Bcmo2 expression was found to be significantly elevated for livers and hepatocytes isolated from Bcmo1-deficient compared to wild type mice. This elevation in Bcmo2 expression was accompanied by a statistically significant increase in hepatic apo-12'-carotenal levels of Bcmo1-deficient mice. Although apo-10'-carotenal, like apo-12'-carotenal, was readily detectable in livers and serum from both wild type and Bcmo1-deficient mice, we were unable to detect either apo-8'- or apo-14'-carotenals in livers or serum from the two strains. We further observed that hepatic triglyceride levels were significantly elevated in livers of Bcmo1-deficient mice fed a β-carotene-containing diet compared to mice receiving no β-carotene. Collectively, our data establish that HSCs are an important cellular site for β-carotene accumulation and metabolism within the liver., (Copyright © 2010 Elsevier Inc. All rights reserved.)

Published
2010
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24. Loss of carotene-9',10'-monooxygenase expression increases serum and tissue lycopene concentrations in lycopene-fed mice.

Author

Ford NA, Clinton SK, von Lintig J, Wyss A, and Erdman JW Jr

Subjects
Animals, Body Weight, Carotenoids administration & dosage, Carotenoids blood, Chromatography, High Pressure Liquid, DNA Primers, Fatty Acid Desaturases genetics, Lycopene, Mice, Mice, Inbred C57BL, Organ Size, Placebos, Polymerase Chain Reaction, RNA, Messenger genetics, Carotenoids metabolism, Fatty Acid Desaturases metabolism
Abstract

Two enzymes have been identified for the oxidative metabolism of carotenoids in mammals. Carotene-15,15'-monooxygenase (CMO-I) primarily centrally cleaves β,β-carotene to form vitamin A. We hypothesize that carotene-9',10'-monooxygenase (CMO-II) plays a key role in metabolism of acyclic nonprovitamin A carotenoids such as lycopene. We investigated carotenoid bioaccumulation in young adult, male, wild-type (WT) mice or mice lacking CMO-II (CMO-II KO). Mice were fed an AIN-93G diet or identical diets supplemented with 10% tomato powder, 130 mg lycopene/kg diet (10% lycopene beadlets), or placebo beadlets for 4 or 30 d. Lycopene preferentially accumulated in CMO-II KO mouse tissues and serum compared with WT mouse tissues. β-Carotene preferentially accumulated in some CMO-II KO mouse tissues compared with WT mouse tissues. Relative tissue mRNA expression of CMO-I and CMO-II was differentially expressed in mouse tissues, and CMO-II, but not CMO-I, was expressed in mouse prostate. In conclusion, the loss of CMO-II expression leads to increased serum and tissue concentrations of lycopene in tomato-fed mice.

Published
2010
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25. A mutation in the silver gene leads to defects in melanosome biogenesis and alterations in the visual system in the zebrafish mutant fading vision.

Author

Schonthaler HB, Lampert JM, von Lintig J, Schwarz H, Geisler R, and Neuhauss SC

Subjects
Amino Acid Sequence, Animals, Base Sequence, Chromosomes, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Genetic Linkage, Genetic Markers, Genome, Homozygote, Melanocytes ultrastructure, Melanosomes ultrastructure, Molecular Sequence Data, Photoreceptor Cells, Vertebrate ultrastructure, Pigment Epithelium of Eye ultrastructure, Polymorphism, Genetic, Protein Sorting Signals, Protein Structure, Tertiary, Radiation Hybrid Mapping, Sequence Analysis, DNA, Sequence Analysis, Protein, Sequence Homology, Amino Acid, Vision, Ocular genetics, Zebrafish embryology, Zebrafish physiology, Zebrafish Proteins chemistry, Melanosomes physiology, Point Mutation, Vision, Ocular physiology, Zebrafish genetics, Zebrafish Proteins genetics
Abstract

Forward genetic screens have been instrumental in defining molecular components of visual function. The zebrafish mutant fading vision (fdv) has been identified in such a screen due to defects in vision accompanied by hypopigmentation in the retinal pigment epithelium (RPE) and body melanocytes. The RPE forms the outer most layer of the retina, and its function is essential for vision. In fdv mutant larvae, the outer segments of photoreceptors are strongly reduced in length or absent due to defects in RPE cells. Ultrastructural analysis of RPE cells reveals dramatic cellular changes such as an absence of microvilli and vesicular inclusions. The retinoid profile is altered as judged by biochemical analysis, arguing for a partial block in visual pigment regeneration. Surprisingly, homozygous fdv vision mutants survive to adulthood and show, despite a persistence of the hypopigmentation, a partial recovery of retinal morphology. By positional cloning and subsequent morpholino knock-down, we identified a mutation in the silver gene as the molecular defect underlying the fdv phenotype. The Silver protein is required for intralumenal fibril formation in melanosomes by amylogenic cleavage. Our data reveal an unexpected link between melanosome biogenesis and the visual system, undetectable in cell culture.

Published
2005
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26. Vitamin A formation in animals: molecular identification and functional characterization of carotene cleaving enzymes.

Author

von Lintig J and Vogt K

Subjects
Animals, Blindness, Drosophila Proteins, Drosophila melanogaster enzymology, Drosophila melanogaster genetics, Growth, Humans, Mutation, Organ Specificity, Phylogeny, beta Carotene metabolism, beta-Carotene 15,15'-Monooxygenase, Carotenoids metabolism, Oxygenases genetics, Oxygenases physiology, Vitamin A biosynthesis
Abstract

Vitamin A and its derivatives (retinoids) are essential components in vision; they contribute to pattern formation during development and exert multiple effects on cell differentiation. It has been known for 70 y that the key step in vitamin A biosynthesis is the oxidative cleavage of a carotenoid with provitamin A activity. While a detailed biochemical characterization of the respective enzymes could be achieved in cell-free homogenates, their molecular nature has remained elusive for a long time. Recent research led to the identification of genes encoding two different types of carotene oxygenases from animal species. The molecular cloning of these different types of animal carotene oxygenases establishes the existence of a family of carotenoid metabolizing enzymes in animals heretofore described in plants. With these tools in hands, old questions in vitamin A research can be definitively addressed on the molecular levels contributing to a mechanistic understanding of the regulation of vitamin A homeostasis or tissue specificity of vitamin A formation, with impact on animal physiology and human health.

Published
2004
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