Programmed metabolic syndrome: prenatal undernutrition and postweaning overnutrition.

Maternal nutrient restriction results in intrauterine growth restriction (IUGR) newborns that develop obesity despite normal postweaning diet. The epidemic of metabolic syndrome is attributed to programmed "thrifty phenotype" and exposure to Western diets. We hypothesized that programmed IUGR newborns would demonstrate greater susceptibility to obesity and metabolic abnormalities in response to high-fat diet. From day 10 to term gestation and lactation, control pregnant rats received ad libitum (AdLib) food, whereas study rats were 50% food restricted (FR). Cross-fostering techniques resulted in three offspring groups: control (AdLib/AdLib), FR during pregnancy (FR/AdLib), and FR during lactation (AdLib/FR). At 3 weeks, offspring were weaned to laboratory chow or high-fat calorie diet (9% vs. 17% calorie as fat). Body composition, appetite hormones, and glucose and lipid profiles were determined in 9-mo-old male and female offspring. High-fat diet had no effect on body weight of AdLib/AdLib, but significantly increased weights of FR/AdLib and AdLib/FR offspring. High-fat diet significantly increased body fat, reduced lean body mass, and accentuated plasma leptin but not ghrelin levels in both sexes in all groups. In males, high-fat diet caused a significant increase in glucose levels in all three groups with increased insulin levels in AdLib/AdLib and AdLib/FR, but not in FR/AdLib. In females, high-fat diet had no effect on glucose but significantly increased basal insulin among all three groups. High-fat diet caused hypertriglyceridemia in all three groups although only food-restricted females exhibited hypercholesterolemia. Sex and offspring phenotype-associated effects of high-fat diet indicate differing pathophysiologic mechanisms that require specific therapeutic approaches.

The timing of nutrient restriction during rat pregnancy/lactation alters metabolic syndrome phenotype.

OBJECTIVE: Modulation of growth of intrauterine growth restricted (IUGR) newborns causes either adult obesity or normalization of body weight and fat. We investigated the impact of rapid versus delayed catch-up growth of IUGR offspring on glucose and lipid profiles. STUDY DESIGN: From 10 days to term gestation and through lactation, control pregnant rats received ad libitum food, whereas study rats were 50% food restricted. Cross-fostering techniques were used to examine effects of food restriction during pregnancy and/or lactation periods. Glucose and lipid profiles were determined in offspring at ages 1 day, 3 weeks, and 9 months. RESULTS: Food restriction during pregnancy produced hypoglycemic IUGR pups. Those permitted rapid catch-up growth demonstrated adult obesity with insulin resistance (hyperglycemia/hyperinsulinemia) and hypertriglyceridemia. Conversely, IUGR exhibiting delayed catch-up growth demonstrated normal adult body weight and insulin deficiency (hyperglycemia/hypoinsulinemia) and elevated cholesterol levels as compared with controls. However, these adult offspring had higher glucose though similar insulin levels as control offspring nursed by food restricted dam. CONCLUSION: The timing and the rate of IUGR newborn catch-up growth causes markedly altered adult phenotypes. Although delayed newborn catch-up growth may be beneficial in the prevention of adult obesity, there may be significant adverse effects on pancreatic function.

N-acetyl-cysteine suppresses amniotic fluid and placenta inflammatory cytokine responses to lipopolysaccharide in rats.

OBJECTIVE: Maternal infections may induce placental, amniotic and, potentially, fetal inflammatory responses. As cytokine responses may be mediated by oxidative stress, we determined whether the antioxidant N-acetyl-cysteine (NAC), can attenuate maternally induced amniotic and placental cytokine responses to maternal infection (modeled by lipopolysaccharide [LPS]). STUDY DESIGN: Gestation day 18 pregnant rats were (1) treated with LPS (100 microg/kg, body weight; intraperitoneally) alone; (2) pretreated with NAC (300 mg/kg body weight; intraperitoneally) 30 minutes before LPS; (3) posttreated with NAC 120 minutes after LPS; or (4) treated with NAC 30 minutes before and 120 minutes after LPS. Six hours after LPS administration, maternal serum and amniotic fluid interleukin-6 (IL-6) and IL-10 levels, and placental IL-6 messenger RNA levels were determined. RESULTS: LPS increased maternal serum IL-6 (50 +/- 25 to 3444 +/- 584 pg/mL) and IL-10 (40 +/- 20 to 958 +/- 339 pg/mL) and amniotic fluid IL-6 (59 +/- 25 to 891 +/- 128 pg/mL). Pretreatment and/or posttreatment with NAC attenuated IL-6 in the maternal serum and amniotic fluid and IL-10 in the amniotic fluid. LPS also induced placental IL-6 messenger RNA that was inhibited by treatment with NAC before and after LPS. CONCLUSION: NAC inhibition of inflammatory responses may protect the fetus from potential long-term sequelae.

Permanent reduction in heart and kidney organ growth in offspring of undernourished rat dams.

OBJECTIVE: Maternal undernutrition affects fetal growth and development. We investigated whether maternal food restriction during pregnancy and/or lactation permanently alters organ growth among adult offspring. STUDY DESIGN: From 10 days to term gestation and through 21 days lactation, control pregnant rats received ad libitum food, whereas study rats were 50% food restricted. Cross-fostering techniques were used to examine the effects of food restriction during pregnancy and/or lactation periods. Organs were dissected and weighed (percentage of body weight) at ages 3 weeks and 9 months. RESULTS: Food restriction during pregnancy produced growth-restricted newborns that exhibited catch-up growth that resulted in markedly heavier adult offspring, although with relatively decreased weights of heart, kidney, lung, and brain as compared with controls. Conversely, food restriction during pregnancy/lactation or lactation alone resulted in adult offspring with similar body weights as controls, but with relatively decreased growth of heart and kidney. Males exhibited relatively smaller livers, whereas the females showed relatively smaller adrenal glands. CONCLUSION: Sex-dependent, selective, and permanent changes in relative growth of heart and kidney may increase risk of adult diseases.

Programmed obesity in intrauterine growth-restricted newborns: modulation by newborn nutrition.

The degree of nutrient enhancement during the newborn period may modulate programming of appetite-regulating hormones, body composition, and propensity to adult obesity in intrauterine growth-restricted (IUGR) newborns. Pregnant rats received, from day 10 to term gestation and throughout lactation, ad libitum food (AdLib) or 50% food restriction (FR) to produce IUGR newborns. AdLib vs. FR offspring were studied at day 1, and, to create two distinct groups of newborn catch-up growth (immediate, delayed) among the IUGR newborns, cross-fostering techniques were employed. The four groups of pups at 3 wk were IUGR immediate catch-up growth (FR/AdLib), IUGR delayed catch-up growth (FR/FR), control (AdLib/AdLib), and lactation FR control (AdLib/FR). From 3 wk to 9 mo, all offspring had AdLib rat chow. Maternal FR during pregnancy resulted in IUGR pups (6.0 +/- 0.3 vs. 7.1 +/- 0.3 g, P < 0.01) with decreased leptin (0.66 +/- 0.03 vs. 1.63 +/- 0.12 ng/ml, P < 0.001) and increased ghrelin (0.43 +/- 0.03 vs. 0.26 +/- 0.02 ng/ml, P < 0.001). Maternal FR during lactation (FR/FR) further impaired IUGR offspring growth at 3 wk. However, by 9 mo, these pups attained normal body weight, percent body fat, and plasma leptin levels. Conversely, IUGR offspring nursed by AdLib dams (FR/AdLib) exhibited rapid catch-up growth at 3 wk and continued accelerated growth, resulting in increased weight, percent body fat, and plasma leptin levels. Thus the degree of newborn nutrient enhancement and timing of IUGR newborn catch-up growth may determine the programming of orexigenic hormones and offspring obesity.