TY - GEN A1 - Stuetz, Wolfgang A1 - Weber, Daniela A1 - Dollé, Martijn E. T. A1 - Jansen, Eugène A1 - Grubeck-Loebenstein, Beatrix A1 - Fiegl, Simone A1 - Toussaint, Olivier A1 - Bernhardt, Juergen A1 - Gonos, Efstathios S. A1 - Franceschi, Claudio A1 - Sikora, Ewa A1 - Moreno-Villanueva, María A1 - Breusing, Nicolle A1 - Grune, Tilman A1 - Bürkle, Alexander T1 - Plasma carotenoids, tocopherols, and retinol in the age-stratified (35–74 years) general population BT - a cross-sectional study in six European countries T2 - Nutrients N2 - Blood micronutrient status may change with age. We analyzed plasma carotenoids, α-/γ-tocopherol, and retinol and their associations with age, demographic characteristics, and dietary habits (assessed by a short food frequency questionnaire) in a cross-sectional study of 2118 women and men (age-stratified from 35 to 74 years) of the general population from six European countries. Higher age was associated with lower lycopene and α-/β-carotene and higher β-cryptoxanthin, lutein, zeaxanthin, α-/γ-tocopherol, and retinol levels. Significant correlations with age were observed for lycopene (r = −0.248), α-tocopherol (r = 0.208), α-carotene (r = −0.112), and β-cryptoxanthin (r = 0.125; all p < 0.001). Age was inversely associated with lycopene (−6.5% per five-year age increase) and this association remained in the multiple regression model with the significant predictors (covariables) being country, season, cholesterol, gender, smoking status, body mass index (BMI (kg/m2)), and dietary habits. The positive association of α-tocopherol with age remained when all covariates including cholesterol and use of vitamin supplements were included (1.7% vs. 2.4% per five-year age increase). The association of higher β-cryptoxanthin with higher age was no longer statistically significant after adjustment for fruit consumption, whereas the inverse association of α-carotene with age remained in the fully adjusted multivariable model (−4.8% vs. −3.8% per five-year age increase). We conclude from our study that age is an independent predictor of plasma lycopene, α-tocopherol, and α-carotene. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 449 KW - carotenoids KW - plasma KW - age KW - Europe KW - micronutrient KW - lycopene KW - retinol KW - tocopherols Y1 - 2018 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-407659 ER - TY - GEN A1 - Henze, Andrea A1 - Raila, Jens A1 - Kempf, Caroline A1 - Reinke, Petra A1 - Sefrin, Anett A1 - Querfeld, Uwe A1 - Schweigert, Florian J. T1 - Vitamin A metabolism is changed in donors after living-kidney transplantation BT - an observational study N2 - Background The kidneys are essential for the metabolism of vitamin A (retinol) and its transport proteins retinol-binding protein 4 (RBP4) and transthyretin. Little is known about changes in serum concentration after living donor kidney transplantation (LDKT) as a consequence of unilateral nephrectomy; although an association of these parameters with the risk of cardiovascular diseases and insulin resistance has been suggested. Therefore we analyzed the concentration of retinol, RBP4, apoRBP4 and transthyretin in serum of 20 living-kidney donors and respective recipients at baseline as well as 6 weeks and 6 months after LDKT. Results As a consequence of LDKT, the kidney function of recipients was improved while the kidney function of donors was moderately reduced within 6 weeks after LDKT. With regard to vitamin A metabolism, the recipients revealed higher levels of retinol, RBP4, transthyretin and apoRBP4 before LDKT in comparison to donors. After LDKT, the levels of all four parameters decreased in serum of the recipients, while retinol, RBP4 as well as apoRBP4 serum levels of donors increased and remained increased during the follow-up period of 6 months. Conclusion LDKT is generally regarded as beneficial for allograft recipients and not particularly detrimental for the donors. However, it could be demonstrated in this study that a moderate reduction of kidney function by unilateral nephrectomy, resulted in an imbalance of components of vitamin A metabolism with a significant increase of retinol and RBP4 and apoRBP4 concentration in serum of donors. T3 - Zweitveröffentlichungen der Universität Potsdam : Mathematisch-Naturwissenschaftliche Reihe - 373 KW - Donors KW - glomerular filtration rate KW - kidney transplantation KW - retinol KW - retinol-binding protein 4 KW - transthyretin Y1 - 2017 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus4-400942 ER - TY - THES A1 - Frey, Simone K. T1 - Investigations on extra- and intracellular retinol-binding proteins T1 - Untersuchungen zu extra- und intrazellulären Retinol-Bindungsproteinen N2 - The fat-soluble vitamin A, which is chemically referred to retinol (ROH), is known to be essential for the process of vision, the immune system but also for cell differentiation and proliferation. Recently, ROH itself has been reported to be involved in adipogenesis and a ROH transport protein, the retinol-binding protein 4 (RBP4), in insulin resistance and type 2 diabetes. However, there is still considerable scientific debate about this relation. With the increasing amount of studies investigating the relation of ROH in obesity and type 2 diabetes, basic research is an essential prerequisite for interpreting these results. This thesis enhances the knowledge on this relation by reviewing ROH metabolism on extra- and intracellular level. Aim 1: In the blood stream ROH is transported in a complex with RBP4 and a second protein, transthyretin (TTR), to the target cells. The levels of RBP4 and TTR are influenced by several factors but mainly by liver and kidney function. The reason for that is that liver and the kidneys are the sites of RBP4 synthesis and catabolism, respectively. Interestingly, obesity and type 2 diabetes involve disorders of the liver and the kidneys. Therefore the aim was to investigate factors that influence RBP4 and TTR levels in relation to obesity and type 2 diabetes (Part 1). Aim 2: Once arrived in the target cell ROH is bound to cellular retinol-binding protein type I (CRBP-I) and metabolised: ROH can either be stored as retinylesters or it can be oxidised to retinoic acid (RA). By acting as a transcription factor in the nucleus RA may influence processes such as adipogenesis. Therefore vitamin A has been postulated to be involved in obesity and type 2 diabetes. CRBP-I is known to mediate the storage of ROH in the liver, but the extra-hepatic metabolism and the functions of CRBP-I are not well known. This has been investigated in Part 2 of this work. Material & Methods: RBP4 and TTR levels were investigated by ELISA in serum samples of human subjects with overweight, type 2 diabetes, kidney or liver dysfunction. Molecular alterations of the RBP4 and TTR protein structure were analysed by MALDI-TOF mass spectrometry. The functions of intracellular CRBP-I were investigated in CRBP-I knock-out mice in liver and extra-hepatic tissues by measuring ROH levels as well as the levels of its storage form, the retinylesters, using reverse phase HPLC. The postprandial uptake of ROH into tissues was analysed using labelled ROH. The mRNA levels of enzymes that metabolize ROH were examined by real-time polymerase chain reaction (RCR). Results: The previous published results showing increased RBP4 levels in type 2 diabetic patients could not be confirmed in this work. However, it could be shown that during kidney dysfunction RBP4 levels are increased and that RBP4 and TTR levels are decreased during liver dysfunction. The important new finding of this work is that increased RBP4 levels in type 2 diabetic mice were increased when kidney function was decreased. Thus an increase in RBP4 levels in type 2 diabetes may be the effect of a reduced kidney function which is common in type 2 diabetes. Interestingly, during severe kidney dysfunction the molecular structure of RBP4 and TTR was altered in a specific manner which was not the case during liver diseases and type 2 diabetes. This underlines the important function of the kidneys in RBP4 metabolism. CRBP-I has been confirmed to be responsible for the ROH storage in the liver since CRBP-I knock-out mice had decreased ROH and retinylesters (the storage form of ROH) levels in the liver. Interestingly, in the adipose tissue (the second largest ROH storage tissue in the body) ROH and retinylesters levels were higher in the CRBP-I knock-out compared to the wild-type mice. It could be shown in this work that a different ROH binding protein, cellular retinol-binding protein type III, is upregulated in CRBP-I knock-out mice. Moreover enzymes were identified which mediate very efficiently ROH esterification in the adipose tissue of the knock-out mice. In the pancreas there was a higher postprandial ROH uptake in the CRBP-I knock-out compard to wild-type mice. Even under a vitamin A deficient diet the knock-out animals had ROH and retinylesters levels which were comparable to wild-type animals. These results underline the important role of ROH for insulin secretion in the pancreas. Summing up, there is evidence that RBP4 levels are more determined by kidney function than by type 2 diabetes and that specific molecular modifications occur during kidney dysfunction. The results in adipose tissue and pancreas of CRBP-I knock-out mice support the hypothesis that ROH plays an important role in glucose and lipid metabolism. N2 - Vitamin A gehört zur Gruppe der fettlöslichen Vitamine und wird chemisch als Retinol bezeichnet. Es ist essentiell für den Prozess des Sehvorgangs und der Zelldifferenzierung und kann daher bestimmte Entwicklungsprozesse wie die Bildung des Fettgewebes beeinflussen. Aufgrund seiner Fettlöslichkeit muss Retinol im Blut (= extrazellulär) sowie in der Zelle (= intrazellulär) an sogenannte Transport-Moleküle, die Retinol-bindenden Proteine (RBPs) gebunden werden. Die zwei bekanntesten Vertreter der RBPs sind das Retinol-bindende Protein 4 (RBP4) und das intrazelluläre Retinol-bindende Protein Typ I (CRBP-I). RBP4 transportiert Vitamin A im Blut von der Leber zur Zielzelle und zum Abbauorgan für Vitamin A, der Niere. CRBP-I ist in der Leber für die Speicherung von Vitamin A zuständig. In den letzten Jahren wurden neben der Beteiligung des Retinols an der Bildung des Fettgewebes auch Studien veröffentlicht, in denen ein Zusammenhang zwischen erhöhten RBP4-Werte im Blut und Typ-2-Diabetes gezeigt wurde. Bis heute ist der mögliche Zusammenhang zwischen RBP4, CRBP-I und Übergewicht nicht ausreichend erforscht. Im ersten Teil der Arbeit war daher das Ziel, Einflussfaktoren, die zu Veränderungen der RBP4-Werte im Blut führen können, zu untersuchen. Dazu wurden Blutproben von Personen mit Übergewicht und/oder Typ-2-Diabetes und Patienten mit Nierenfunktionsstörungen oder mit Leberfunktionsstörungen analysiert. Es konnte gezeigt werden, dass bereits geringe Nierenfunktionsstörungen zu erhöhten RBP4-Konzentrationen im Blut führten. Bei Typ-2-Diabetikern, die sehr oft an Nierenfunktionsstörungen leiden, war eine Erhöhung der RBP4-Konzentration mit einer Abnahme der Nierenfunktion verbunden. Somit lässt sich zusammenfassen, dass nicht Typ-2-Diabetes sondern vielmehr die dabei auftretenden Nierenfunktionsstörungen zu einer Erhöhung der RBP4-Werte führen. Bei Lebererkrankten konnte ein Absinken der RBP4-Werte nachgewiesen werden, was der verminderten Bildung von RBP4 in der Leber bei diesen Patienten zuzuschreiben ist. Im zweiten Teil sollte der Frage nachgegangen werden, wie Retinol intrazellulär verstoffwechselt wird. Dabei lag der Fokus auf der Erforschung der bisher nicht bekannten Funktionen von CRBP-I im Fettgewebe und der Bauchspeicheldrüse. Zur Untersuchung der Funktionen von CRBP-I wurden Mäuse gezüchtet, bei denen das Gen für CRBP-I gelöscht wurde. Da CRBP-I für die Speicherung von Vitamin A in der Leber verantwortlich ist, zeigen diese Mäuse sehr geringe Vitamin-A-Speicher in der Leber. Das gleiche zeigte sich für die Bauchspeicheldrüse, die für die Sekretion von Insulin Vitamin A benötigt: In den Mäusen ohne CRBP-I waren die Retinol-Werte drastisch gesunken. Interessanterweise zeigte sich im Fettgewebe ein gegenteiliges Bild: Die Konzentrationen an Retinol und dessen Speicher waren in den Mäusen ohne CRBP-I höher im Vergleich zu den normalen Mäusen. Mit bestimmten Nachweismethoden konnte herausgefunden werden, dass Retinol im Fettgewebe an ein anderes RBP, das CRBP-III, gebunden wird und dadurch effektiver gespeichert werden kann als durch CRBP-I. KW - Vitamin A KW - retinol KW - RBP KW - Retinol-Bindungsprotein 4 KW - Diabetes KW - Vitamin A KW - retinol KW - RBP KW - Retinol-binding protein 4 KW - diabetes Y1 - 2009 U6 - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-31428 ER -