Bol V V, Delattre A-I, Reusens B, Raes M, Remacle C
Laboratory of Cell Biology Institute of Life Science, Université catholique de Louvain, Place Croix du Sud 5, 1348 Louvain-la-Neuve, Belgium.
Am J Physiol Regul Integr Comp Physiol. 2009 Aug;297(2):R291-9. doi: 10.1152/ajpregu.90497.2008. Epub 2009 May 20.
A mismatch between fetal and postnatal environment can permanently alter the body structure and physiology and therefore contribute later to obesity and related disorders, as revealed by epidemiological studies. Early programming of adipose tissue might be central in this observation. Moreover, adipose tissue secretes adipokines that provide a molecular link between obesity and its related disorders. Therefore, our aim was to investigate whether a protein restriction during fetal life, followed by catch-up growth could lead to obesity in 9-mo-old male mice and could alter the adipose tissue gene expression profile. Dams were fed a low-protein (LP) or an isocaloric control (C) diet during gestation. Postnatal catch-up growth was induced in LP offspring by feeding dams with control diet and by culling LP litters to four pups instead of eight in the C group. At weaning, male mice were fed by lab chow alone (C) or supplemented with a hypercaloric diet (HC), to induce obesity (C-C, C-HC, LP-C, and LP-HC groups). At 9 mo, LP offspring featured increased relative fat mass, hyperglycemia, hypercholesterolemia, and hyperleptinemia. Using a microarray designed to study the expression of 89 genes involved in adipose tissue differentiation/function, we demonstrated that the expression profile of several genes were dependent upon the maternal diet. Among the diverse genes showing altered expression, we could identify genes encoding several enzymes involved in lipid metabolism. These results indicated that offspring submitted to early mismatched nutrition exhibited alterations in adipose tissue gene expression that probably increases their susceptibility to overweight when challenged after weaning with a HC diet.
流行病学研究表明,胎儿与出生后环境之间的不匹配会永久性地改变身体结构和生理机能,进而导致日后肥胖及相关疾病。脂肪组织的早期编程可能是这一现象的核心所在。此外,脂肪组织会分泌脂肪因子,在肥胖及其相关疾病之间建立了分子联系。因此,我们的目的是研究胎儿期蛋白质限制后再经历追赶生长,是否会导致9月龄雄性小鼠肥胖,并改变脂肪组织基因表达谱。在妊娠期间,给母鼠喂食低蛋白(LP)或等热量对照(C)饮食。通过给LP组母鼠喂食对照饮食,并将LP组窝仔数减少至4只(而C组为8只),诱导LP组后代出生后追赶生长。断奶时,雄性小鼠单独喂食实验室饲料(C组)或补充高热量饮食(HC组)以诱导肥胖(C-C、C-HC、LP-C和LP-HC组)。9月龄时,LP组后代的相对脂肪量增加、血糖升高、高胆固醇血症和高瘦素血症。使用一个旨在研究89个参与脂肪组织分化/功能的基因表达的微阵列,我们证明了几个基因的表达谱取决于母体饮食。在表达发生改变的多种基因中,我们能够鉴定出编码几种参与脂质代谢的酶的基因。这些结果表明,早期营养不匹配的后代脂肪组织基因表达发生改变,断奶后用HC饮食挑战时,可能会增加其超重的易感性。
