Effects of periconceptional undernutrition and twinning on ovine pregnancy

Rumball, Christopher William Henry

January 2008

Events around conception such as maternal undernutrition and twinning may have effects on offspring physiology and disease risk in adulthood. Periconceptional undernutrition alters offspring physiology and adult pathology without affecting birth size, while twinning affects birth size and physiology but with inconsistent effects on adult pathology. We investigated the effects of these two periconceptional events and their interaction on maternal cardiovascular adaptation to pregnancy and fetal growth, physiology and endocrinology in late gestation in sheep. Pre and/or postconception undernutrition resulted in increased uterine blood flow in late gestation, but no change in maternal blood volume. Preconception undernutrition alone resulted in a relatively large placenta with a small, slow-growing fetus in late gestation. In contrast, postconception undernutrition alone resulted in a fetus with rapid late-gestation growth that was maintained through a maternal fast. Fetuses of ewes undernourished throughout both periods were similar in growth rate and size to controls. Maternal fasting also demonstrated that plasma levels of C-type natriuretic peptide are acutely and independently regulated by nutrient supply in mother and fetus. Fetuses of ewes undernourished both pre- and postconception had increased glucose disposal following a glucose challenge. Hypothalamic-pituitary-adrenal axis tests in these fetuses showed decreased pituitary adrenocorticotropin hormone response to direct stimulation but increased adrenal response to decreased cortisol negative feedback. Twin fetuses grew more slowly in late gestation than singletons. Twins also had a smaller insulin response to arginine and a greater insulin response to glucose, but periconceptional undernutrition abolished this difference. Twins had suppressed baseline hypothalamic-pituitary-adrenal axis function and decreased adrenal sensitivity compared to singletons, but increased fetal pituitary adrenocorticotropin hormone response to direct stimulation and decreased cortisol negative feedback. These studies suggest that firstly, fetal size is a poor reflection of fetal growth trajectory, physiology and endocrinology. Secondly, pre- and postconception undernutrition affect late-gestation fetal growth in different ways, while undernutrition in both periods alters fetal endocrine status in late gestation. Thirdly, the biology of twin fetal development is fundamentally different from that of singletons, which may explain the inconsistency of the relationship between birth weight and adult disease risk in twins. / Auckland Medical Research Foundation, Health Research Council of New Zealand

sheep

pregnancy

fetal programming

nutrition

twins

hypothalamic-pituitary-adrenal axis

glucose-insulin axis

fetal growth

Effects of periconceptional undernutrition and twinning on ovine pregnancy

Rumball, Christopher William Henry

January 2008

Events around conception such as maternal undernutrition and twinning may have effects on offspring physiology and disease risk in adulthood. Periconceptional undernutrition alters offspring physiology and adult pathology without affecting birth size, while twinning affects birth size and physiology but with inconsistent effects on adult pathology. We investigated the effects of these two periconceptional events and their interaction on maternal cardiovascular adaptation to pregnancy and fetal growth, physiology and endocrinology in late gestation in sheep. Pre and/or postconception undernutrition resulted in increased uterine blood flow in late gestation, but no change in maternal blood volume. Preconception undernutrition alone resulted in a relatively large placenta with a small, slow-growing fetus in late gestation. In contrast, postconception undernutrition alone resulted in a fetus with rapid late-gestation growth that was maintained through a maternal fast. Fetuses of ewes undernourished throughout both periods were similar in growth rate and size to controls. Maternal fasting also demonstrated that plasma levels of C-type natriuretic peptide are acutely and independently regulated by nutrient supply in mother and fetus. Fetuses of ewes undernourished both pre- and postconception had increased glucose disposal following a glucose challenge. Hypothalamic-pituitary-adrenal axis tests in these fetuses showed decreased pituitary adrenocorticotropin hormone response to direct stimulation but increased adrenal response to decreased cortisol negative feedback. Twin fetuses grew more slowly in late gestation than singletons. Twins also had a smaller insulin response to arginine and a greater insulin response to glucose, but periconceptional undernutrition abolished this difference. Twins had suppressed baseline hypothalamic-pituitary-adrenal axis function and decreased adrenal sensitivity compared to singletons, but increased fetal pituitary adrenocorticotropin hormone response to direct stimulation and decreased cortisol negative feedback. These studies suggest that firstly, fetal size is a poor reflection of fetal growth trajectory, physiology and endocrinology. Secondly, pre- and postconception undernutrition affect late-gestation fetal growth in different ways, while undernutrition in both periods alters fetal endocrine status in late gestation. Thirdly, the biology of twin fetal development is fundamentally different from that of singletons, which may explain the inconsistency of the relationship between birth weight and adult disease risk in twins. / Auckland Medical Research Foundation, Health Research Council of New Zealand

sheep

pregnancy

fetal programming

nutrition

twins

hypothalamic-pituitary-adrenal axis

glucose-insulin axis

fetal growth

Identifying the mechanisms of antidepressant drug action in mice lacking brain serotonin

Petermann, Markus

13 July 2021

Serotonin gilt als Hauptangriffsstelle gängiger Antidepressiva bei schweren Depressionen, wie bspw. selektive Serotonin-Wiederaufnahmehemmer (SSRI), und -Enhancer (SSRE). Es bleibt offen, ob SSRI / E ausschließlich über die Manipulation des Serotoninspiegels wirken, oder ob alternative Signalwege daran beteiligt sind. Ansatzpunkte hierfür sind beispielsweise die neurotrophen Signalwege (spez. Brain derived neurotophic factor, BDNF) oder die Hypothalamus-Hypophysen-Nebennieren- (HPA) – Signalwege des Stressachsensystems. Ebenfalls wurde in Nagetiermodellen beobachtet, dass mit der Dysregulation des zentralen Serotoninsystems bei schweren Depressionen, ein Rückgang der Neurogenese im Gyrus dentatus des Hippocampus einhergeht. Ziel dieser Arbeit war, das Zusammenspiel von Serotonin, BDNF, adulter Neurogenese und der Stressachse zu untersuchen. Zentrum der Studien ist ein Mausmodell, mit einer genetischen Depletion des zentralen Serotonin-synthetisierenden Enzyms Tryptophanhydroxylase 2 (sog. Tph2-/- Mäuse). Es wurden die physiologische Reaktionen auf die Behandlung mit gängigen Antidepressiva abhängig von der Abwesenheit von Serotonin untersucht, um mögliche alternative Signalwege aufzeigen zu können. Die bekannte Zunahme der Neurogenese nach SSRI/SSRE-Behandlung wurde in Wildtyptieren beobachtet, während die Therapie in Tph2-/- Mäusen keine direkte kausale Wirkung zeigte. Im Gegensatz dazu waren die BDNF-Spiegel in depressionsrelevanten Hirnregionen in Tph2-/- Mäusen nach SSRI, signifikant verringert. Auch zeigen die Studien eine neurobiologische Relevanz von Serotonin im ZNS, bei den antidepressiven Mechanismen einer Elektrokonvulsiven Krampftherapie. Ebenfalls deuten erhöhte Neurogeneseraten bei lebenslanger Abwesenheit von Serotonin im ZNS, Therapiemethoden-unabhängig, möglicherweise auf eine modulierte Stressreaktion hin. Untersuchungen der Parameter des HPA-Stressachsensystems, wiesen auf einen grundlegend veränderten Stresshormonspiegel in Tph2-/- Mäusen hin. / Serotonin, the "molecule of happiness" is an important target for antidepressants. The mainly prescribed drugs in major depression are selective serotonin re-uptake inhibitors (SSRI); but recently, SSR-enhancer (SSRE) have also attracted clinical attention. However, only a quarter of patients responds to treatment. It needs to be determined, whether SSRI/E act solely via manipulating serotonin levels or whether other pathways are involved, e.g. neurotrophic signaling (brain-derived neurotrophic factor, BDNF) or the hypothalamus-pituitary-adrenal (HPA)-axis. Furthermore, in major depression, dysregulation of central serotonin signaling is accompanied with a decline in hippocampal neurogenesis, as has been observed in rodent models. At the center of this thesis is a mouse model deficient in the central serotonin-synthesizing enzyme, tryptophan hydroxylase 2 (Tph2-/- mice). I have investigated physiological responses to antidepressant treatment in the absence of brain serotonin, and the possible role of alternative pathways. I observed the typical increase in neurogenesis upon SSRI treatment in WT mice, while it had no effect in Tph2-/- mice. In contrast, BDNF levels were significantly decreased in Tph2-/- mice after treatment with no effect in WT control mice. Furthermore, my results show a critical role of brain serotonin in the neurobiological effects of electroconvulsive seizure. Surprisingly, in animals lacking central serotonin, increased neurogenesis was observed independently of the treatment. The gathered data indicated an altered stress response; therefore, parameters of the HPA-axis have been studied, indicating a downregulated HPA system in Tph2-/-animals in baseline state, but showed no difference in treatment or feedback control. This thesis gives insight into the mechanisms of antidepressant action and reveals ideas for novel pathways involved in the process that could be used as targets in therapeutic approaches and further research in major depression.

Depression

SSRI

SSRE

Citalopram

Tianeptin

Elektrokonvulsionstherapie

EKT

ECS

Neurogenese

BDNF

HPA-Achse

Antidepressiva

Serotonin

TPH2

Depression

SSRI

SSRE

Citalopram

Tianeptine

Electro convulsive therapy

ECT

ECS

Neurogenesis

BDNF

Hypothalamic–pituitary–adrenal axis

HPA-axis

Antidepressives

Serotonin

TPH2

570 Biologie

571 Physiologie und verwandte Themen

615 Pharmakologie und Therapeutik

VS 7107

YH 6212

YH 6213

YH 6215

WD 5832

ddc:570

ddc:571

ddc:573

ddc:615