6 results on '"Johannes von Lintig"'
Search Results
2. Astaxanthin-Shifted Gut Microbiota Is Associated with Inflammation and Metabolic Homeostasis in Mice
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Minghua Tang, Guadalupe Davilla El-Rassi, Tyrrell Conway, Edralin A. Lucas, Yi Lyu, Xinchun Shen, Babajide Ojo, Brenda J. Smith, Johannes von Lintig, Dingbo Lin, Wu Jinlong, Hui He, Katherine Metzinger, Lei Wu, Ramkumar Srinivasagan, Stephen L. Clarke, and Winyoo Chowanadisai
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0301 basic medicine ,Male ,medicine.medical_specialty ,Medicine (miscellaneous) ,Inflammation ,Gut flora ,Xanthophylls ,medicine.disease_cause ,Dioxygenases ,03 medical and health sciences ,chemistry.chemical_compound ,Mice ,0302 clinical medicine ,Astaxanthin ,Internal medicine ,medicine ,Animals ,Homeostasis ,chemistry.chemical_classification ,Mice, Knockout ,Nutrition and Dietetics ,biology ,Bacteria ,Chemistry ,Fatty acid ,Akkermansia ,biology.organism_classification ,Glucagon-like peptide-1 ,Animal Feed ,Diet ,Gastrointestinal Microbiome ,030104 developmental biology ,Endocrinology ,030220 oncology & carcinogenesis ,Dietary Supplements ,Female ,Nutrient Physiology, Metabolism, and Nutrient-Nutrient Interactions ,medicine.symptom ,Energy Metabolism ,Oxidative stress ,Akkermansia muciniphila - 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
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- 2020
3. Overlapping Vitamin A Interventions with Provitamin A Carotenoids and Preformed Vitamin A Cause Excessive Liver Retinol Stores in Male Mongolian Gerbils
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Michael Grahn, Philipp W. Simon, Gabrielle Simons, Luciana Mourao, Kevin V. Pixley, Mikayla Kaeppler, Sherry A. Tanumihardjo, Jesse Sheftel, Christopher R Davis, Margaret Sowa, and Johannes von Lintig
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Vitamin ,Male ,White Carrot ,Biofortification ,Medicine (miscellaneous) ,Orange (colour) ,Zea mays ,chemistry.chemical_compound ,Animal science ,Original Research Articles ,Animals ,Drug Interactions ,Vitamin A ,Carotenoid ,chemistry.chemical_classification ,Nutrition and Dietetics ,biology ,Dose-Response Relationship, Drug ,Retinol ,biology.organism_classification ,Animal Feed ,Carotenoids ,SCARB1 ,Daucus carota ,chemistry ,Liver ,Gerbillinae - 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.
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- 2019
4. Lycopene and Apo-10′-lycopenoic Acid Have Differential Mechanisms of Protection against Hepatic Steatosis in β-Carotene-9′,10′-oxygenase Knockout Male Mice
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Chun Liu, Johannes von Lintig, Blanche C. Ip, Alice H. Lichtenstein, and Xiang-Dong Wang
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Male ,medicine.medical_specialty ,Nutrition and Disease ,Saturated fat ,Medicine (miscellaneous) ,AMP-Activated Protein Kinases ,Diet, High-Fat ,Dioxygenases ,Mice ,chemistry.chemical_compound ,Lycopene ,Sirtuin 1 ,AMP-activated protein kinase ,Internal medicine ,Nonalcoholic fatty liver disease ,medicine ,Animals ,PPAR alpha ,Phosphorylation ,Triglycerides ,UCP3 ,Mice, Knockout ,Nutrition and Dietetics ,biology ,Forkhead Box Protein O1 ,Cholesterol ,Fatty Acids ,Fatty liver ,Forkhead Transcription Factors ,medicine.disease ,Carotenoids ,Up-Regulation ,Fatty Liver ,PPAR gamma ,Endocrinology ,Adipose Tissue ,Liver ,chemistry ,Fatty Acids, Unsaturated ,biology.protein ,Cholesteryl ester ,ATP-Binding Cassette Transporters ,Female ,Steatosis ,Biomarkers ,Stearoyl-CoA Desaturase ,Acetyl-CoA Carboxylase ,Signal Transduction - 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.
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- 2015
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5. Loss of Carotene-9′,10'-Monooxygenase Expression Increases Serum and Tissue Lycopene Concentrations in Lycopene-Fed Mice
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Nikki A. Ford, Johannes von Lintig, John W. Erdman, Steven K. Clinton, and Adrian Wyss
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Vitamin ,chemistry.chemical_classification ,medicine.medical_specialty ,Nutrition and Dietetics ,Antioxidant ,genetic structures ,medicine.medical_treatment ,Carotene ,Retinol ,Medicine (miscellaneous) ,Monooxygenase ,Biology ,eye diseases ,Lycopene ,chemistry.chemical_compound ,Endocrinology ,Biochemistry ,chemistry ,beta-Carotene ,Internal medicine ,medicine ,sense organs ,Carotenoid - 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.
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- 2010
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6. Vitamin A Formation in Animals: Molecular Identification and Functional Characterization of Carotene Cleaving Enzymes
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Johannes von Lintig and Klaus Vogt
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Vitamin ,Oxygenase ,medicine.medical_treatment ,Cellular differentiation ,Medicine (miscellaneous) ,Growth ,Molecular cloning ,Biology ,Blindness ,chemistry.chemical_compound ,medicine ,Animals ,Drosophila Proteins ,Humans ,Vitamin A ,Gene ,Carotenoid ,Phylogeny ,beta-Carotene 15,15'-Monooxygenase ,chemistry.chemical_classification ,Nutrition and Dietetics ,Carotene ,beta Carotene ,Carotenoids ,Drosophila melanogaster ,Enzyme ,chemistry ,Biochemistry ,Organ Specificity ,Mutation ,Oxygenases - 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.
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- 2004
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