Doctoral Degrees (Anatomy and Histology)
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Browsing Doctoral Degrees (Anatomy and Histology) by Subject "Glucose"
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- ItemThe effect of an in utero high fat diet on the expression of transcription factors and glucose sensing in the developing rat pancreas(Stellenbosch : Stellenbosch University, 2005-12) Cerf, Marlon Eugene; Du Toit, D. F.; Louw, J.; Stellenbosch University. Faculty of Medicine and Health Sciences. Dept. of Biomedical Sciences. Anatomy and Histology.ENGLISH ABSTRACT: A high fat diet (HFD) reduces beta-cell mass, impairs glucose signalling and is involved in the development of Type 2 diabetes. Malnutrition during gestation is hypothesized to irreversibly damage beta-cell development. The transcription factors Pdx-1 and Pax 4 are involved in islet cell development. Pdx-1 is reported to regulate expression of GLUT-2, glucokinase (GK) and the insulin gene. Aims The aim of this study is to investigate, in the neonatal and weanling rat, the effect of exposure to a HFD in utero and/or lactation on weight, glucose and insulin concentrations, islet cell development, pancreatic transcription factors and glucose sensing genes. Methods Neonatal and weanling rats were exposed to a maternal HFD for defined periods of gestation and/or lactation. After termination, pups were weighed and glucose and insulin concentrations determined. mRNA expression of Pdx-1, Pax 4, GLUT-2 and GK was quantified by LightCycler PCR. Pancreatic sections were immunostained for insulin and glucagon (islet cell development), and for Pdx-1, GLUT-2 and GK (beta-cell function) followed by image analysis. Results: Exposure to an in utero HFD throughout gestation resulted in hyperglycaemic pups with reduced beta-cell volume and number, Pdx-1 and GK immunoreactivity. In contrast the alpha-cell volume, number and size were augmented in neonates exposed to a HFD throughout gestation. Most weanlings were hyperglycaemic and hypoinsulinaemic. In some weanlings, reduced beta-cell number and beta- and alpha-cell size was observed. Pdx-1 mRNA was overexpressed in weanlings exposed to a maternal HFD for the final week of gestation or throughout both gestation and lactation, but reduced in those only exposed throughout lactation. Pax 4 mRNA was reduced in weanlings exposed to a maternal HFD for the first or final week of gestation, throughout gestation or throughout lactation. In most of the weanlings, GLUT-2 mRNA expression was reduced whereas immunoreactivity for GLUT-2 was increased. Both GK mRNA expression and immunoreactivity were reduced in most of the weanlings. Conclusions • Exposure to an in utero HFD throughout gestation induced hyperglycaemia in neonates. The reduced Pdx-1 expression appears to play a role in the compromised beta-cell development, and concomitant with the reduced GK levels, contributes to the hyperglycaemia in these neonates and may make them susceptible to beta-cell failure. • In most weanlings exposed to a HFD in utero and/or during lactation the hyperglycaemia and hypoinsulinaemia suggest compromised beta-cell function. The GK mRNA expression and immunoreactivity were reduced thereby impairing glycolysis which would result in reduced insulin secretion contributing to the hyperglycaemia. Furthermore, beta-cell development is adversely affected by the HFD in some weanlings. This would contribute to reduced beta-cell function and may eventually result in beta-cell failure. GLUT-2 immunoreactivity was increased in some, suggesting a compensatory adaptative mechanism to restore glucose homeostasis. • A maternal HFD has adverse effects both in neonates and weanlings on beta-cell development, transcription factor and glucose sensing gene expression and induced hyperglycaemia and hypoinsulinaemia in some of the offspring. Ways to ameliorate the HFD-induced attenuation of key beta-cell genes to ensure normal beta-cell function are important for future research in Type 2 diabetes.