Your search keyword '"Freek G Bouwman"' showing total 2 results

1. The Physiologic Effects of Caloric Restriction Are Reflected in the in Vivo Adipocyte-Enriched Proteome of Overweight/Obese Subjects

Author

Edwin C. M. Mariman, Mandy Claessens, Ping Wang, Jean-Paul Noben, Marleen A. van Baak, Freek G. Bouwman, Wim H. M. Saris, Humane Biologie, RS: NUTRIM - R4 - Gene-environment interaction, and RS: NUTRIM - R1 - Metabolic Syndrome

Subjects

Adult, Male, Proteomics, medicine.medical_specialty, Proteome, Normal diet, food.diet, Adipose tissue, Biology, Biochemistry, ACADS, chemistry.chemical_compound, food, Weight loss, Adipocyte, Internal medicine, Weight Loss, Adipocytes, medicine, Humans, Obesity, Adiposity, Caloric Restriction, Proteins, Lipid metabolism, General Chemistry, Middle Aged, Overweight, Lipid Metabolism, Very low calorie diet, Endocrinology, chemistry, Female, medicine.symptom

Abstract

We have applied our recently designed proteomics apparoach to search for protein changes in the in vivo adipocyte-enriched proteome from 8 overweight/obese subjects who underwent an intervention of 5 weeks of a very low calorie diet followed by 3 weeks of a normal diet. On average, persons lost 9.5 kg body weight largely contributed by the loss of fat mass (7.1 kg). Various parameters of adiposity and lipid metabolism changed significantly. Proteomics analysis revealed 6 significantly changed proteins. Analysis indicates that fructose-bisphosphate aldolase C and tubulin beta 5 are potential biomarkers for the present intervention. Further, identified proteins indicate a reduced intracellular scaffolding of GLUT4 (ALDOC, TUBB5, ANXA2), an increased uptake of fatty acids (FABP4), an improved inflammatory profile of the adipose tissue (ApoA1, AOP1) and a change in fat droplet organization (vimentin). Correlation analysis between changes in protein spot intensities and parameters of adiposity or lipid metabolism points to a link between aldo-ketoreductase 1C2 and parameters of adiposity, between FABP4 and parameters of lipid metabolism, and between proteins for beta-oxidation (HADH, ACADS, ACAT1) and FFA levels. Altogether, our findings underscore the potential value of in vivo proteomics for human intervention studies.

Published

2009

2. Starvation Induces Phase-Specific Changes in the Proteome of Mouse Small Intestine

Author

Johan Renes, Kaatje Lenaerts, Freek G. Bouwman, Edwin C. M. Mariman, Wouter H. Lamers, Milka Sokolović, Other departments, Amsterdam Gastroenterology Endocrinology Metabolism, Medical Biology, Humane Biologie, Anatomie en Embryologie, and RS: NUTRIM School of Nutrition and Translational Research in Metabolism

Subjects

Starvation, GPX3, Mucin, General Chemistry, Biology, Proteomics, Biochemistry, Small intestine, Cell biology, medicine.anatomical_structure, Proteome, medicine, medicine.symptom, Starvation response, Carbonic anhydrase 3

Abstract

Food deprivation results in metabolic, structural, and functional changes in the small intestine that influences gut mucosal integrity, epithelial cell proliferation, mucin synthesis, and other processes. The underlying mechanisms are still unclear, which lead to the study of molecular effects of short-term and long-term starvation in the intestine of mice. A comparative proteomics approach, combining two-dimensional gel electrophoresis with matrix-assisted laser desorption/ionization time-of-flight mass spectrometry, was used to identify intestinal proteins whose expression is changed under different starvation conditions (0, 12, 24, and 72 h). In total, the expression levels of 80 protein spots changed significantly between the different groups. The results demonstrate that after 12 h of starvation, mainly proteins involved in glycolysis and energy metabolism show decreased expression levels. Starvation for 24 h results in a down-regulation of proteins involved in protein synthesis and amino acid metabolism. Simultaneously, proteins with a protective role, e.g., reg I and II, glutathione peroxidase 3, and carbonic anhydrase 3, are clearly up-regulated. The last starvation phase (72 h) is characterized by increased ezrin expression, which may enhance villus morphogenesis critical for survival. Together, these results provide novel insights in the intestinal starvation response and may contribute to improved nutritional support during conditions characterized by malnutrition.

Published

2006