The work in this thesis describes the fundamental role of Lkb1 as a conductor of metabolism-related processes in zebrafish larvae. We show that Lkb1 is essential for the regulation of glucose... Show moreThe work in this thesis describes the fundamental role of Lkb1 as a conductor of metabolism-related processes in zebrafish larvae. We show that Lkb1 is essential for the regulation of glucose metabolism, the activation of autophagy, and hematopoiesis under conditions of metabolic stress. Furthermore, we also uncovered gene transcription profiles and hematological characteristics that are specific to lkb1 larvae, and independent of metabolic stress. Finally, we illustrate and highlight the potential of lkb1 larvae as screening platform in research related to metabolism, hematopoiesis, and tumors bearing LKB1 mutations. Overall, we have strengthened the value of lkb1 zebrafish larvae as a model to study the effects of Lkb1-inactivation on various metabolism-related processes Show less
This thesis aims to describe the role of glucose metabolism in human longevity and to translate the results to an intervention aimed at improving health in older age in the general population. In... Show moreThis thesis aims to describe the role of glucose metabolism in human longevity and to translate the results to an intervention aimed at improving health in older age in the general population. In the first part, we describe evidence for enhanced glucose metabolism in long-lived families. Middle-aged individuals predisposed to longevity were characterized by enhande insulin action at the level of the skeletal muscle, lower accumulation of intramyocellular lipids and lower nocturnal glucose levels. These results have provided the biological basis upon which health-promoting intervention in older age may be funded. In the second part, we have shonw that an internet-based intervention is effective at increasing physical activity and improving health in an older population. Furthermore, increasing total daily physical activity in sedentary elderly was shown to lead to better metabolic health. Show less
There is a fundamental difference between mammals and fish in how hypoxia affects the lipid metabolism by means of the stress hormone noradrenaline. In mammals, hypoxia induces an increase in lipid... Show moreThere is a fundamental difference between mammals and fish in how hypoxia affects the lipid metabolism by means of the stress hormone noradrenaline. In mammals, hypoxia induces an increase in lipid metabolism, which can eventually lead to tissue damage due to elevated plasma fatty acid levels, e.g. in case of a heart attack. However, hypoxia is not a normally occurring situation in healthy mammals as opposed to many fish species, because water is a relative poor source of oxygen. In hypoxic fish therefore, noradrenaline mediates a decrease in lipid metabolism, and we believe that this is a general protection mechanism in fish against lipid poisoning. There is a clear difference in the mode of breathing between mammals and fish, namely air- vs. water-breathing. Hence, we hypothesise that this difference is the cause for the opposing effects of noradrenaline. Therefore, we studied the effects of hypoxia on an air-breathing fish, the African catfish. However, physiologically this species reacted the same as other water-breathing fish, namely by means of a reduced lipid metabolism. Additionally, we demonstrated that, despite the opposing effects on the lipid metabolism, the transduction pathways in fish and mammals are very alike, and thus only a minor change has occurred in the course of evolution. This research has aided in a better understanding of the evolutionary changes in lipid metabolism.|Er is een fundamenteel verschil tussen zoogdieren en vissen in hoe het vetmetabolisme onder hypoxie (=zuurstoftekort) wordt veranderd door het stresshormoon noradrenaline. In zoogdieren leidt hypoxie tot een verhoogd vetmetabolisme, wat uiteindelijk zelfs weefselschade kan veroorzaken door te hoge vetzuurgehaltes, b.v. bij een hartaanval. Gezonde zoogdieren komen normaliter niet in zuurstofnood, in tegenstelling tot veel vissoorten, omdat water een relatief arme zuurstofbron is. In hypoxische vissen daalt dan ook het vetmetabolisme door noradrenaline, en wij denken dat dit een beschermingsmechanisme is tegen een vetzuurvergiftiging. Er is een duidelijk verschil in de manier van ademhalen van zoogdieren en vissen, respectievelijk lucht- en waterademhaling, en dit verschil ligt mogelijkerwijs ten grondslag aan deze verschillende effecten van noradrenaline; dit is de centrale hypothese van het onderzoek. Daarom is gekeken naar het effect van zuurstoftekort bij een luchtademhalende vissoort, de Afrikaanse meerval. Deze vis bleek echter fysiologisch hetzelfde te reageren als waterademhalende vissen, namelijk een verlaagd vetmetabolisme. Daarnaast is aangetoond dat, ondanks tegenovergestelde effecten op het vetmetabolisme, de aansturingmechanismen in vissen en zoogdieren vergelijkbaar zijn, en dat er dus maar een minimale verandering in de evolutie heeft plaatsgevonden. Dit onderzoek heeft bijgedragen tot een beter begrip van de evolutionaire veranderingen in het vetmetabolisme. Show less