TY  - THES
A1  - Andres, Janin
T1  - Untersuchungen über Regulationsmechanismen der 11beta-Hydroxysteroid Dehydrogenase Typ 1
T1  - Analysis of regulation of 11beta-Hydroxysteroid dehydrogenase type 1
N2  - Die 11beta-HSD1 reguliert intrazellulär die Cortisolkonzentration durch Regeneration von Cortison z.B. aus dem Blutkreislauf, zu Cortisol. Daher stellt diese ein wichtiges Element in der Glucocorticoid-vermittelten Genregulation dar. Die 11beta-HSD1 wird ubiquitär exprimiert, auf hohem Niveau besonders in Leber, Fettgewebe und glatten Muskelzellen. Insbesondere die Bedeutung der 11beta-HSD1 in Leber und Fettgewebe konnte mehrfach nachgewiesen werden. In der Leber führte eine erhöhte Aktivität aufgrund einer Überexpression in Mäusen zu einer verstärkten Gluconeogeneserate. Des Weiteren konnte gezeigt werden, dass eine erhöhte Expression und erhöhte Enzymaktivität der 11beta-HSD1 im subkutanen und viszeralen Fettgewebe assoziiert ist mit Fettleibigkeit, Insulinresistenz und Dyslipidämie. Über die Regulation ist jedoch noch wenig bekannt. Zur Untersuchung der Promotoraktivität wurde der Promotorbereich von -3034 bis +188, vor und nach dem Translations- und Transkriptionsstart, der 11beta-HSD1 kloniert. 8 Promotorfragmente wurden mittels Dual-Luciferase-Assay in humanen HepG2-Zellen sowie undifferenzierten und differenzierten murinen 3T3-L1-Zellen untersucht. Anschließend wurde mittels nicht-radioaktiven EMSA die Bindung des TATA-Binding Proteins (TBP) sowie von CCAAT/Enhancer-Binding-Proteinen (C/EBP) an ausgewählte Promotorregionen analysiert. Nach der Charakterisierung des Promotors wurden spezifische endogene und exogene Regulatoren untersucht. Fettsäuren modifizieren die Entstehung von Adipositas und Insulinresistenz. Ihre Wirkung wird u.a. PPARgamma-abhängig vermittelt und kann durch das Inkretin (Glucose-dependent insulinotropic Peptide) GIP modifiziert werden. So wurden die Effekte von unterschiedlichen Fettsäuren, vom PPARgamma Agonisten Rosiglitazon sowie dem Inkretin GIP auf die Expression und Enzymaktivität der 11beta-HSD1 untersucht. Dies wurde in-vitro-, tierexperimentell und in humanen in-vivo-Studien realisiert. Zuletzt wurden 2 Single Nucleotide Polymorphismen (SNP) im Promotorbereich der 11beta-HSD1 in der Zellkultur im Hinblick auf potentielle Funktionalität analysiert sowie die Assoziation mit Diabetes mellitus Typ 2 und Körpergewicht in der MeSyBePo-Kohorte bei rund 1.800 Personen untersucht. Die Luciferase-Assays zeigten basal eine zell-spezifische Regulation der 11beta-HSD1, wobei in allen 3 untersuchten Zelltypen die Bindung eines Repressors nachgewiesen werden konnte. Zudem konnte eine mögliche Bindung des TBPs sowie von C/EBP-Proteinen an verschiedene Positionen gezeigt werden. Die Transaktivierungsassays mit den C/EBP-Proteinen -alpha, -beta und -delta zeigten eben-falls eine zellspezifische Regulation des 11beta-HSD1-Promotors. Die Aktivität und Expression der 11beta-HSD1 wurde durch die hier untersuchten endogenen und exogenen Faktoren spezifisch modifiziert, was sowohl in-vitro als auch in-vivo in unterschiedlichen Modellsystemen dargestellt werden konnte. Die Charakterisierung der MeSyBePo-Kohorte ergab keine direkten Assoziationen zwischen Polymorphismus und klinischem Phänotyp, jedoch Tendenzen für eine erhöhtes Körper-gewicht und Typ 2 Diabetes mellitus in Abhängigkeit des Genotyps. Der Promotor der 11beta-HSD1 konnte aufgrund der Daten aus den Luciferaseassays sowie den Daten aus den EMSA-Analysen näher charakterisiert werden. Dieser zeigt eine variable und zell-spezifische Regulation. Ein wichtiger Regulator stellen insbesondere in den HepG2-Zellen die C/EBP-Proteine -alpha, -beta und -delta dar. Aus den in-vivo-Studien ergab sich eine Regulation der 11beta-HSD1 durch endogene, exogene und pharmakologische Substanzen, die durch die Zellkulturversuche bestätigt und näher charakterisiert werden konnten.
N2  - The enzyme 11beta-HSD1 regulates intracellular the cortisol concentration by regeneration of cortisone to cortisol. Hence, 11beta-HSD1 is an important factor in glucocorticoid-mediated gene expression. It is ubiquitously expressed, but high levels have been specifically described in liver, adipose tissue and smooth muscle cells. A pivotal role for 11beta-HSD1 has been demonstrated with respect to metabolism in liver and adipose tissue. Thus, a liver-specific overexpression results in an elevated gluconeogenesis and hepatic glucose output. Furthermore, a fat-specific overexpression was associated with obesity, insulin resistance and dyslipidemia. Despite these intriguing data, the regulation of the human 11beta-HSD1 gene is still in its infancies. 8 promoter fragments from -3034 to +188 of 11beta-HSD1-gene were cloned to analyze promoter activity. Dual-Luciferase-Assay was used in humane HepG2 cells and in undifferentiated and differentiated 3T3-L1 cells. Furthermore, the region close to the transcription start was studied with a non-radioactive EMSA for binding of TATA-binding protein (TBP) and CCAAT/enhancer-binding-protein (C/EBP). The role of the endogenous and exogenous regulators fatty acids, PPARgamma and the incretin (Glucose-dependent insulinotropic Peptide) GIP was investigated in-vitro and in-vivo. Finally, the functional consequences of 2 Single Nucleotide Polymorphisms (SNP) within the promoter region were studied in cell culture and the MeSyBePo-cohorts for association with diabetes mellitus type 2 and body weight. The Luciferase-assay revealed a cell-specific regulation of 11beta-HSD1 and a repressor, which was active in all 3 cell models. Accordingly, a cell-specific regulation was observed in transactivation-assays with C/EBP-proteins -alpha, -beta and -delta. The 11beta-HSD1 enzyme expression and activity was specifically modified by the here investigated endogenous and exogenous factors, which was demonstrated in-vitro but also in-vivo in various experimental settings. The characterisation of the MeSyBePo-cohorte revealed no association between genotype and clinical phenotype, although a trend for an increased body weight and diabetes mellitus type 2 was detected. This work demonstrated a cell-specific regulation of the 11beta-HSD1 promoter. Furthermore, a binding site for TATA-binding proteins was detected in HepG2 and undifferentiated 3T3-L1 cells. A pivotal role in regulation of 11beta-HSD1 promoter activity was demonstrated for the C/EBP-proteins, especially in liver cells. The in-vivo-Studies revealed a regulation of enzyme expression and activity by endogenous, exogenous and pharmacological substances, which was confirmed and analyzed in more detail in cell culture experiments.
KW  - Promotor
KW  - 11beta-HSD1
KW  - Fettleibigkeit
KW  - Diabetes
KW  - Regulation
KW  - Promoter
KW  - 11beta-HSD1
KW  - Obesity
KW  - Diabetes
KW  - Regulation
Y1  - 2008
U6  - http://nbn-resolving.de/urn/resolver.pl?urn:nbn:de:kobv:517-opus-33033
ER  - 
TY  - JOUR
A1  - Hoffmann, Svenja
A1  - Warschburger, Petra
T1  - Body image in obese children and adolescents. Body dissatisfaction and body size perception in relation to quality of life and weight loss
JF  - Psychotherapeut
N2  - Body dissatisfaction and an unrealistic perception of own body size are particularly common in obese children and adolescents; however, little is known about the association with weight-related quality of life and the impact on successful long-term weight loss.
 At the beginning of an inpatient child obesity rehabilitation program, 408 children and adolescents aged 9-12 years completed a questionnaire on body image (body silhouettes) and a body weight-specific questionnaire for overweight and obese children and adolescents (GW-LQ-KJ) on quality of life. Height and weight were measured by a physician at the beginning and 1 year after inpatient hospitalization.
 Of the participants 91.9 % reported body dissatisfaction and 75.7 % underestimated their own body size. There were no gender-specific differences in body dissatisfaction but boys perceived their body size more realistically than girls. Participants with body dissatisfaction and realistic body size perception showed a reduced weight-related quality of life. Those participants who realistically perceived their body size also lost less weight in the long term.
 The subjective underestimation of body size proved to be important for reduced weight-related quality of life and more pronounced long-term weight loss; therefore, body image should be taken into account in multimodal treatment programs.
KW  - Body size perception
KW  - Quality of life
KW  - Weight loss
KW  - Obesity
KW  - Questionnaire
Y1  - 2015
U6  - https://doi.org/10.1007/s00278-015-0060-5
SN  - 0935-6185
SN  - 1432-2080
VL  - 60
IS  - 6
SP  - 498
EP  - 504
PB  - Springer
CY  - New York
ER  - 
TY  - JOUR
A1  - Stadion, Mandy
A1  - Schürmann, Annette
T1  - Intermittent fasting
T1  - Intermittierendes Fasten
BT  - What effects does it have in humans?
BT  - Welche Effekte hat es beim Menschen?
JF  - Psychotherapeut
N2  - A long-term positive energy balance leads to overweight and obesity. Adiposity is the main risk factor for cardiovascular diseases, type 2 diabetes and cancer and is often accompanied by depression. The increasing prevalence creates a major problem for the healthcare system. The conservative management of obesity strives for weight loss by reducing the daily caloric intake and increasing physical activity as well as an improvement in the quality of life supported by psychological interventions. For reducing body weight, intermittent fasting represents an alternative to continuous calorie restriction as it can be easily integrated into daily life. In this form of diet calorie intake is limited in time, i.e. on 2 days in the week or 6-10 h per day. Animal and human studies provide evidence that intermittent fasting over a longer time period is a suitable method to decrease body fat and to improve many metabolic parameters. Fasting alters metabolism and activates specific cellular pathways. These have not only cardioprotective effects but also neuroprotective and antidepressive effects. In this article the currently discussed mechanisms induced by intermittent fasting are highlighted and the essential observations from randomized controlled human trials are presented.
KW  - Obesity
KW  - Brain-derived neurotrophic factor
KW  - Insulin sensitivity
KW  - Metabolic flexibility
KW  - Circadian rhythm
Y1  - 2020
U6  - https://doi.org/10.1007/s00278-020-00471-5
SN  - 0935-6185
SN  - 1432-2080
VL  - 66
IS  - 1
SP  - 23
EP  - 27
PB  - Springer
CY  - New York
ER  -