Administration of growth hormone or IGF-I to pregnant rats on a reduced diet throughout pregnancy does not prevent fetal intrauterine growth retardation and elevated blood pressure in adult offspring.

Increasing evidence from human epidemiological studies suggests that poor growth before birth is associated with postnatal growth retardation and the development of cardiovascular disease in adulthood. We have shown previously that nutritional deprivation in the pregnant rat leads to intrauterine growth retardation (IUGR), postnatal growth failure, changes in the endocrine parameters of the somatotrophic axis, and to increased blood pressure in later life. In the present study, we investigated whether administration of insulin-like growth factor-I (IGF-I) or bovine growth hormone (GH) during pregnancy could prevent IUGR and/or alter long-term outcome. Dams from day 1 of pregnancy throughout gestation received a diet of ad libitum available food or a restricted dietary intake of 30% of ad libitum fed dams. From day 10 of gestation, dams were treated for 10 days with three times daily subcutaneous injections of saline (100 microl), IGF-I (2 micrograms/g body weight) or GH (2 micrograms/g body weight). Maternal weight gain was significantly increased (P<0.001) in ad libitum fed dams treated with GH, (98.9+/-4.73 g) compared with the IGF-I (80.5+/-2.17 g) and saline-treated (70.7+/-2.65 g) groups. There was a small increase in maternal weight gain (P<0.06) in 30% ad libitum fed dams following GH (16.3+/-2.47 g) and IGF-I (15.8+/-1.97 g) treatment compared with saline (9.2+/-1.96 g). Whole spleen, kidney and carcass weights were significantly (P<0.05) increased in ad libitum fed and 30% ad libitum fed dams with GH treatment. Circulating IGF-I was significantly increased (P<0.001) in ad libitum fed dams with both IGF-I (369.6+/-32.33 ng/ml) and GH (457.9+/-33.32 ng/ml) compared with saline treatment (211.7+/-14.02 ng/ml), and with GH (223.4+/-23.72 ng/ml) compared with saline treatment (112.0+/-7.33 ng/ml) in 30% ad libitum fed dams. Circulating GH binding protein (GHBP) levels were significantly reduced (P<0.05) in GH-treated (299.1+/-51.54 ng/ml) compared with saline-treated (503.9+/-62.43 ng/ml) ad libitum fed dams, but were not altered in 30% ad libitum fed dams. There was no significant effect of either IGF-I or GH treatment on fetal weight, placental weight, fetal organ weights or circulating IGF-I levels in both ad libitum fed and 30% ad libitum fed fetuses. Offspring of 30% ad libitum fed dams remained significantly growth retarded postnatally and showed elevated blood pressure in later life. The increased maternal weight gain following IGF-I or GH administration, without an effect on fetal and placental weights, suggests a modification in the mode of maternal nutrient repartitioning during mid to late pregnancy at the expense of the fetus.     

Effects of food restriction and pregnancy on the expression of insulin-like growth factors-I and -II in tIssues from guinea pigs

The insulin-like growth factor (IGF) system is subjected to pregnancy-associated changes in the circulation and is suggested to be of importance for partitioning of nutrients between the mother and the foetus. Interestingly, maternal undernutrition alters the pregnancy-associated changes, with possible adverse consequences for the mother and the foetus. However, it is not known how malnutrition and pregnancy alter the expression of mRNA for IGFs locally in different tIssues. The aims of this study were to investigate where IGF-I and IGF-II are expressed in guinea pigs and how this expression is altered during food restriction and pregnancy. Ad libitum-fed and food-restricted (fed 70% of the ad libitum-fed intake four weeks before pregnancy and throughout the study) guinea pigs were mated. On day 40 of pregnancy and on the corresponding day for virginal females the animals were killed. mRNA for IGF-I and IGF-II was analysed in various organs/tIssues by solution hybridisation. mRNA for IGF-I was expressed in high amounts in uterus, liver and adipose tIssues. The expression was not affected by food restriction, but was increased in liver and adipose tIssue and decreased in uterus by pregnancy. mRNA for IGF-II was expressed in high amounts in the placenta and liver. In the placenta the expression was decreased by food restriction. Pregnancy increased the levels of mRNA for IGF-II in the liver. Food-restricted dams had smaller foetuses and placentas. In conclusion, this study indicates an important role for the adipose tIssue during gestation, not only as an energy store but also as an endocrine tIssue expressing IGF-I. The decreased expression of IGF-II in the placenta due to food restriction is suggested to have adverse effects on placental structure and function.     

Maternal insulin-like growth factors-I and -II act via different pathways to promote fetal growth

The placenta transports substrates and wastes between the maternal and fetal circulations. In mice, placental IGF-II is essential for normal placental development and function but, in other mammalian species, maternal circulating IGF-II is substantial and may contribute. Maternal circulating IGFs increase in early pregnancy, and early treatment of guinea pigs with either IGF-I or IGF-II increases placental and fetal weights by mid-gestation. We now show that these effects persist to enhance placental development and fetal growth and survival near term. Pregnant guinea pigs were infused with IGF-I, IGF-II (both 1 mg/kg.d), or vehicle sc from d 20-38 of pregnancy and killed on d 62 (term = 69 d). IGF-II, but not IGF-I, increased the mid-sagittal area and volume of placenta devoted to exchange by approximately 30%, the total volume of trophoblast and maternal blood spaces within the placental exchange region (+29% and +46%, respectively), and the total surface area of placenta for exchange by 39%. Both IGFs reduced resorptions, and IGF-II increased the number of viable fetuses by 26%. Both IGFs increased fetal weight by 11-17% and fetal circulating amino acid concentrations. IGF-I, but not IGF-II, reduced maternal adipose depot weights by approximately 30%. In conclusion, increased maternal IGF-II abundance in early pregnancy promotes fetal growth and viability near term by increasing placental structural and functional capacity, whereas IGF-I appears to divert nutrients from the mother to the conceptus. This suggests major and complementary roles in placental and fetal growth for increased circulating IGFs in early to mid-pregnancy.     

Early pregnancy maternal endocrine insulin-like growth factor I programs the placenta for increased functional capacity throughout gestation

In early pregnancy, the concentrations of IGFs increase in maternal blood. Treatment of pregnant guinea pigs with IGFs in early to midpregnancy enhances placental glucose transport and fetal growth and viability near term. In the current study, we determined whether exogenous IGFs altered placental gene expression, transport, and nutrient partitioning during treatment, which may then persist. Guinea pigs were infused with IGF-I, IGF-II (both 1 mg/kg x d) or vehicle sc from d 20-35 of pregnancy and killed on d 35 (term is 70 d) after administration of [(3)H]methyl-D-glucose (MG) and [(14)C]amino-isobutyric acid (AIB). IGF-I increased placental and fetal weights (+15 and +17%, respectively) and MG and AIB uptake by the placenta (+42 and +68%, respectively) and fetus (+59 and +90%, respectively). IGF-I increased placental mRNA expression of the amino acid transporter gene Slc38a2 (+780%) and reduced that of Igf2 (-51%), without altering the glucose transporter Slc2a1 or Vegf and Igf1 genes. There were modest effects of IGF-I treatment on MG and AIB uptake by individual maternal tissues and no effect on plasma glucose, total amino acids, free fatty acids, triglycerides, and cholesterol concentrations. IGF-II treatment of the mother did not alter any maternal, fetal or placental parameter. In conclusion, exogenous IGF-I, but not IGF-II, in early pregnancy increases placental transport of MG and AIB, enhancing midgestational fetal nutrient uptake and growth. This suggests that early pregnancy rises in maternal circulating IGF-I play a major role in regulating placental growth and functional development and thus fetal growth throughout gestation.     

Administration of growth hormone to pregnant rats on a reduced diet inhibits growth of their fetuses

During gestation, female rats become resistant to the anabolic actions of GH. The importance of this resistance for conceptus growth was investigated by treating pregnant dams on a reduced diet with ovine (o) or bovine (b) GH during days 10-20 of gestation. Reducing food intake to 60% that of ad libitum-fed controls significantly depleted maternal inguinal fat stores by day 20 of gestation, but it did not affect the growth of the fetuses or the placentas. In the food-restricted dams, twice daily injections of oGH (1 mg/day) or bGH (5 mg/day) during days 10-20 of gestation increased their inguinal fat pad wet weight by 28% and 62%, respectively, but had no effect on the wet weight of maternal heart, liver, or spleen. The dams treated with bGH had significantly heavier kidneys than the PBS- or oGH-treated females. On day 20 of gestation, control animals fed a 60%-diet had total serum insulin-like growth factor-I levels that were depressed to the same extent as those in ad libitum fed dams (i.e. to about 25% of the levels in nonpregnant females). Both the oGH and bGH treatments significantly elevated maternal serum insulin-like growth factor-I to 42% and 300%, respectively, of the levels in the untreated underfed dams. Compared to virgin controls, maternal tibial epiphyseal plate width was also significantly diminished in dams fed ad libitum or a 60% diet. Nevertheless, oGH and bGH were effective at augmenting maternal tibial epiphyseal plate width to equal those in virgin controls. Both doses of GH significantly reduced placental and fetal weights compared to those of PBS-injected dams on a 60% diet, and dams treated with the higher dose of GH were in an advanced stage of fetal and placental resorption by day 20 of gestation. Thus, maternal resistance to the anabolic actions of GH appears to be an important adaptation for diverting nutrients from the mother to the fetus.     

Late pregnancy increases hepatic expression of insulin-like growth factor-I in well nourished guinea pigs.

Blood IGF-I concentrations are persistently elevated throughout pregnancy in humans and guinea pigs and may regulate substrate partitioning between mother and conceptus. In the guinea pig, liver and adipose tissue have recently been suggested to contribute to the increased levels of circulating IGF-I in mid-pregnancy, but whether this persists in late pregnancy in undernutrition is not known. Therefore the effect of pregnancy and undernutrition on circulating IGF-I and hepatic expression of IGF-I in late gestation in the guinea pig was examined. Female guinea pigs (Cavia porcellus) were fed ad libitum throughout pregnancy or 70% of ad libitum intake for 28 days prior to and throughout pregnancy (term is 69 d). Non-pregnant animals were maintained for 88 days on the same diets. Plasma IGF-I was measured by RIA after molecular sieving chromatography at low pH. Abundances of IGF-I and beta-actin mRNA in maternal liver were quantified by digoxigenin-ELISA after RT PCR. Late pregnancy increased both the concentration of IGF-I protein (p<0.001) in plasma and the relative abundance of liver IGF-I mRNA (p<0.001) in ad libitum fed, but not in feed restricted pregnant guinea pigs. The concentration of IGF-I protein in plasma correlated positively with the relative abundance of IGF-I mRNA in liver overall (p<0.002), suggesting the liver as a major source of endocrine IGF-I in late pregnant guinea pigs. This study demonstrates that hepatic expression of IGF-I remains elevated during late pregnancy in the well fed guinea pig, which is in contrast to that observed in other non-human species.     

Maternal nutrition alters the expression of insulin-like growth factors in fetal sheep liver and skeletal muscle

We investigated the influence of maternal dietary restriction between days 28 and 80 of gestation followed by re-feeding to the intake of well-fed ewes up to 140 days of gestation (term is 147 days) in sheep, on expression of mRNA for insulin-like growth factor (IGF)-I, IGF-II and growth hormone receptor (GHR) in fetal liver and skeletal muscle. Singleton bearing ewes either consumed 3.2-3.8 MJ/day of metabolisable energy (ME) (i.e. nutrient restricted - approximately 60% of ME requirements, taking into account requirements for both ewe maintenance and growth of the conceptus) or 8.7-9.9 MJ/day (i.e. well fed - approximately 150% of ME requirements) between days 28 and 80 of gestation. All ewes were then well fed (150% of ME requirements) up to day 140 of gestation and consumed 8-10.9 MJ/day. At days 80 and 140 of gestation, five ewes were sampled from each group and fetal tissues taken. There was no difference in fetal body weight or liver weights between groups at either sampling date, or skeletal muscle (quadriceps) weight at 140 days. IGF-I mRNA abundance was lower in livers of nutrient-restricted fetuses at day 80 of gestation (nutrient restricted 2.35; well fed 3.70 arbitrary units), but was higher than well-fed fetuses at day 140 of gestation, after 60 days of re-feeding (restricted/re-fed 4.27; well fed 2.83;s.e.d. 0.98 arbitrary units, P=0.061 for dietxage interaction). IGF-II mRNA abundance was consistently higher in livers of nutrient-restricted fetuses (80 days: nutrient restricted 7.78; well fed 5.91; 140 days: restricted/re-fed 7.23; well fed 6.01;s.e.d. 1.09 arbitrary units, P=0.061 for diet). Nutrient restriction had no effect on hepatic GHR mRNA abundance, but re-feeding of previously nutrient-restricted fetuses increased GHR mRNA compared with continuously well-fed fetuses (80 days: nutrient restricted 70.6; well fed 75.1; 140 days: restricted/re-fed 115.7; well fed 89.4;s.e.d. 10.13 arbitrary units, P=0.047 for dietxage interaction). In fetal skeletal muscle, IGF-I mRNA abundance was not influenced by maternal nutrition and decreased with gestation age (P<0.01). IGF-II mRNA abundance was higher in skeletal muscle of nutrient-restricted fetuses compared with well-fed fetuses at day 80 of gestation (nutrient restricted 16.72; well fed 10.53 arbitrary units), but was lower than well-fed fetuses after 60 days of re-feeding (restricted/re-fed 7.77; well fed 13.72;s.e.d. 1.98 arbitrary units, P<0.001 for dietxage interaction). There was no effect of maternal nutrition or gestation age on fetal skeletal muscle GHR expression. In conclusion, maternal nutrient restriction in early to mid gestation with re-feeding thereafter results in alterations in hepatic and skeletal muscle expression of IGF-I, IGF-II and/or GHR in the fetus which may subsequently relate to altered organ and tissue function.     

Treatment of underfed pigs with GH throughout the second quarter of pregnancy increases fetal growth

Circulating growth hormone (GH) concentrations increase in pregnancy and administration of GH during early-mid pregnancy increases fetal growth in well-fed pigs. To determine whether increased maternal GH could promote fetal growth when feed availability is restricted, fifteen cross-bred primiparous sows (gilts) were fed at approximately 30% of ad libitum intake, from mating onwards and were injected daily i.m. with recombinant porcine GH (pGH) at doses of 0, 13.4+/-0.3 and 25.6+/-0.5 microg/kg live weight from day 25 to day 51 of pregnancy (term approximately 115 days). Treatment with pGH increased maternal backfat loss between day 25 and day 51 of pregnancy, and increased maternal plasma IGF-I concentrations measured at day 51 of pregnancy. Fetal body weight, length and skull width at day 51 of pregnancy were increased by maternal treatment with pGH. Fetal plasma glucose concentrations were increased and maternal/fetal plasma glucose concentration gradients were decreased by maternal pGH treatment at 13.4, but not 25.6 microg/kg.day. Fetal plasma concentrations of urea were decreased by both levels of pGH treatment. Overall, fetal weight was negatively correlated with fetal plasma concentrations of urea, positively correlated with maternal plasma alpha-amino nitrogen concentrations and unrelated to glucose concentrations in either maternal or fetal plasma. This suggests that the availability of amino acids, not glucose, limits fetal growth in the first half of pregnancy in underfed gilts, and that maternal GH treatment may improve amino acid delivery to the fetus.     

Effect of Ethanol Exposure on Circulating Levels of Insulin-Like Growth Factor I and II, and Insulin-Like Growth Factor Binding Proteins in Fetal Rats

Maternal ethanol (ETOH) exposure is associated with impaired fetal growth. Because insulin-like growth factors (IGFs) are thought to be important in the regulation of fetal somatic growth, we examined the influence of maternal ETOH exposure on fetal growth and plasma levels of IGF-I, IGF-II, and IGF binding proteins (IGFBPs) in the rat model. Control (A) dams were fed a standard rat chow ad libitum. ETOH (E) consuming dams were fed a 36% ETOH diet, and pair-fed (P) dams were fed isocaloric amounts of a control liquid diet. All animals were killed on day 20 of gestation. Plasma concentrations of IGF-I and -II were determined by radioimmunoassay after formic acid-acetone extraction and heat inactivation of IGFBPs. Levels of IGFBPs in fetal plasma were estimated by Western ligand blotting after protein separation by SDS-PAGE and electrotransfer to nitrocellulose. Membranes were probed with [¹²⁵l]IGF-l, and IGFBPs were identified by autoradiography, quantified by scanning densitometry and results expressed relative to corresponding IGFBPs in control fetal plasma. Maternal weight gain from conception to 20 days of pregnancy was reduced for E compared to P and A dams (p < 0.05 E vs. P or A). The same pattern was reflected in fetal weight that tended to be lower in P compared with A pups, and was significantly reduced in E pups compared with both groups (p < 0.0001 E vs. P or A). Thus, fetal growth was more retarded in E animals despite equal caloric and protein intake by E and P dams. Radioimmunoassay of fetal plasma revealed that there was no difference in circulating levels of IGF-II in A (65.5 ± 8.7 ng/ml) and P (65.9 ± 9.8 ng/ml) plasma. However, levels of IGF-II were higher in E (87.1 ± 6.2 ng/ml) than in corresponding P animals. At the same time, there were no differences in IGF-I levels between any of the treatment groups. Western ligand blotting demonstrated that levels of 32–34 kDa IGFBPs were elevated in plasma of P compared with A fetal plasma, consistent with an effect of reduced maternal nutrition. In contrast, levels of32–34 kDa IGFBPs were reduced in E plasma compared with P and A (p < 0.04 and p < 0.02, respectively). These data suggest that circulating levels of IGF-II (but not IGF-I) and specific IGFBPs are altered in growth-retarded fetuses exposed to ETOH. Comparison to fetal plasma obtained from pair-fed litters demonstrate that these effects on IGF and IGFBP levels are specific to ETOH, and not simply due to maternal nutrient intake. Taken together, these observations indicate that ETOH has unique effects on fetal IGF physiology compared with previously studied models of fetal growth retardation. Alterations in the expression and levels of IGFs and IGFBPs may contribute to ETOH-induced fetal growth deficiency.     

A short period of maternal nutrient restriction in late gestation modifies pituitary-adrenal function in adult guinea pig offspring

Altered fetal environment can program the hypophyseal-pituitary-adrenal (HPA) axis development and thus affect endocrine function in later life. We hypothesized that 48 h of maternal nutrient restriction during the period of maximal fetal brain growth alters HPA function in adult offspring and leads to modified blood pressure regulation. Pregnant guinea pigs (n = 15) were deprived of food (water ad libitum) or fed normally (n = 13) on days 50 and 51 of gestation, after which they were all fed normally (birth = 68 days). Carotid artery and jugular vein catheters were implanted in adult guinea pig offspring (day 65). Animals were treated with corticotropin (ACTH(1-24); 0.5 microg/kg), corticotropin-releasing hormone (CRH; 0.5 microg/kg) and insulin (5 units/kg), and pituitary-adrenal responses were measured. Guinea pigs were then euthanized and pituitaries removed for analysis of pro-opiomelanocortin (POMC) and glucocorticoid receptor (GR) mRNA levels. There was no effect of prenatal treatment on body weight, blood pressure or heart rate. In male offspring, both basal ACTH (p < 0.007) and basal cortisol (p < 0.05) levels were significantly reduced in animals whose mothers had been nutrient restricted (NR). In contrast, in female offspring, basal plasma ACTH was not different between offspring from NR mothers and controls; however, basal plasma cortisol concentrations were significantly (p < 0.01) elevated at 13.00 h in females born to NR mothers. Responses to HPA challenge were different between offspring from NR mothers and control offspring, and these differences were consistent with alterations in basal adrenocortical function. There was no effect of prenatal treatment on POMC mRNA levels in the pars distalis or pars intermedia. However, GR mRNA levels were significantly (p < 0.05) reduced in adult female offspring born to NR mothers. In conclusion, 48 h of maternal nutrient restriction during pregnancy has a long-term effect on HPA function in adult offspring, and this effect is highly sex specific, but does not result in alteration of blood pressure.     

Maternal endocrine adaptation throughout pregnancy to nutritional manipulation: consequences for maternal plasma leptin and cortisol and the programming of fetal adipose tissue development

Maternal nutrient restriction at specific stages of gestation has differential effects on fetal development such that the offspring are programmed to be at increased risk of adult disease. We investigated the effect of gestational age and maternal nutrition on the maternal plasma concentration of leptin and cortisol together with effects on fetal adipose tissue deposition plus leptin, IGF-I, IGF-II ligand, and receptor mRNA abundance near to term. Singleton bearing ewes were either nutrient restricted (NR; consuming 3.2-3.8 MJ/d of metabolizable energy) or fed to appetite (consuming 8.7-9.9 MJ/d) over the period of maximal placental growth, i.e. between 28 and 80 d gestation. After 80 d gestation, ewes were either fed to calculated requirements, consuming 6.7-7.5 MJ/d, or were fed to appetite and consumed 8.0-10.9 MJ/d. Pregnancy resulted in a rise in plasma leptin concentration by 28 d gestation, which continued up to 80 d gestation when fed to appetite but not with nutrient restriction. Plasma cortisol was also lower in NR ewes up to 80 d gestation, a difference no longer apparent when food intake was increased. At term, irrespective of maternal nutrition in late gestation, fetuses sampled from ewes NR in early gestation possessed more adipose tissue, whereas when ewes were fed to appetite throughout gestation, fetal adipose tissue deposition and leptin mRNA abundance were both reduced. These changes may result in the offspring of NR mothers being at increased risk of obesity in later life.     

Expression of the genes for insulin-like growth factor-I (IGF-I), IGF-II, and IGF-binding proteins-1 and -2 in fetal rat under conditions of intrauterine growth retardation caused by maternal fasting.

Evidence suggests that insulin-like growth factors-I and -II (IGF-I and II) play a role in regulating fetal growth and development. In the fetus, IGF-I and -II are complexed with two specific binding proteins (IGFBP-1 and -2), which are thought to modulate the actions of the IGFs in target tissues. We examined regulation of the genes for IGF-I, IGF-II, IGFBP-1, and IGFBP-2 in fetal rat liver in an experimental model for intrauterine growth retardation caused by maternal fasting on days 17-21 of gestation. The mean weight of fetuses from the fasted dams was 27-32% lower than the mean weight of fetuses from the fed dams. The concentration of immunoreactive IGF-I was decreased by 71% in serum of fetuses from the fasting dams. The concentration of immunoreactive IGF-II was slightly decreased (by 12%) in serum of fetuses from the fasting dams, whereas the concentration of immunoreactive pro-IGF-II E-domain peptide was decreased by 31%. The abundance of hepatic IGF-I mRNA was decreased by 55% in fetuses from the fasting dams. In contrast, the abundance of IGF-II mRNA in fetal liver was not significantly decreased by maternal fasting. Maternal fasting caused a 2-fold increase in the abundance of IGFBP-1 mRNA in fetal liver, whereas it did not change the abundance of IGFBP-2 mRNA. The induction of IGFBP-1 mRNA in liver of the growth-retarded fetuses is similar to the induction that occurs in liver of fasting adults, while the lack of regulation of IGFBP-2 mRNA differs from the strong induction of IGFBP-2 mRNA that occurs in liver of fasting adults. In summary, these results indicate that maternal fasting causes a decrease in fetal IGF-I gene expression, a decrease in fetal serum IGF-I, and a slight decrease in fetal serum IGF-II and pro-IGF-II E-domain peptide concentrations. Maternal fasting also causes an increase in fetal IGFBP-1 gene expression. Changes in fetal insulin and glucose may be related to changes in expression of the IGF-I and IGFBP-1 genes in the growth-retarded fetuses. The decreased expression of IGF-I and -II and increased expression of the IGFBP-1 gene may contribute to the fetal growth retardation observed in this model system.     

Elevating maternal insulin-like growth factor-I in mice and rats alters the pattern of fetal growth by removing maternal constraint.

Fetal growth is normally constrained by maternal factors. This constraint is demonstrated by the usual inverse linear relationship between litter size and mean fetal weight. Cross-breeding experiments between mice of lines selected for high or low plasma insulin-like growth factor (IGF-I) levels suggested that elevations in maternal IGF-I abolish (P less than 0.01) this constraining effect and reverse the usual positive relationship between fetal and placental size in late gestation. This was confirmed by treating mice and rats throughout pregnancy with IGF-I. In normal mice and in low IGF-I line mice treatment with IGF-I (10 micrograms 8-hourly s.c. from day 1 to 19 of pregnancy) abolished maternal constraint whereas 0.9% (w/v) NaCl treatment did not. In Wistar rats osmotic pumps were implanted to deliver IGF-I (1 microgram/g body weight per day), bovine GH (bGH; 0.6 microgram/g body weight per day) or saline from day 1 to 19 of pregnancy. IGF-I therapy but not bGH or saline abolished (P less than 0.01) maternal constraint and altered (P less than 0.01) the relationship between placental and fetal weight. When high or low IGF-I line mice embroys were transplanted into a normal line of mice, the expected negative relationship (P less than 0.05) between mean fetal weight and litter size was maintained. However, the embryos of the high line were heavier (P less than 0.05) than those from the low line irrespective of fetal number, suggesting a direct role for IGF-I in the regulation of fetal growth.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metabolic response to starvation at late gestation in chronically ethanol-treated and pair-fed undernourished rats

To study the role of undernourishment in the negative effects of ethanol during pregnancy and to determine whether maternal ethanol intake modifies metabolic response to starvation at late gestation, female rats receiving ethanol in their drinking water before and during pregnancy (ethanol group) were compared with animals that received the same amount of solid diet as the ethanol group rats (pair-fed group) and with normal rats fed ad libitum (control group). All animals were killed on the 21st day of gestation, either in the fed state or after 24-hours fasting. The body weight of ethanol rats was lower than that of controls but higher than that of pair-fed rats. When compared with controls, ethanol and pair-fed rats had reduced fetal body weights, whereas fetal body length was reduced only in the former. In the fed state, blood glucose concentration was lower in the ethanol and pair-fed rats and fetuses than in controls. Twenty-four-hour starvation caused a reduction in this parameter only in control and ethanol mothers. In the fed state, maternal liver glycogen concentration was lower in ethanol and higher in pair-fed mothers than in controls. Blood beta-hydroxybutyrate levels were higher in ethanol-treated mothers than in the others, and 24-hour starvation increased this parameter in ethanol and control rats to a greater extent than in the pair-fed ones. Liver triacylglyceride concentration was higher in ethanol-treated mothers than in the other two groups, and starvation caused this concentration to increase in ethanol and control groups but not in the pair-fed group.(ABSTRACT TRUNCATED AT 250 WORDS)     

IGF-I treatment reduces hyperphagia, obesity, and hypertension in metabolic disorders induced by fetal programming

The discovery of a link between in utero experience and later metabolic and cardiovascular disease is one of the most important advances in epidemiology research of recent years. There is increasing evidence that alterations in the fetal environment may have long-term consequences on cardiovascular, metabolic, and endocrine pathophysiology in adult life. This process has been termed programming, and we have shown that undernutrition of the mother during gestation leads to programming of hyperphagia, obesity, hypertension, hyperinsulinemia, and hyperleptinemia in the offspring. Using this model of maternal undernutrition throughout pregnancy combined with postnatal hypercaloric nutrition of the offspring, we examined the effects of IGF-I therapy. Virgin Wistar rats (age 75 +/- 5 d, n = 20 per group) were time mated and randomly assigned to receive food either ad libitum or 30% of ad libitum intake (UN) throughout pregnancy. At weaning, female offspring were assigned to one of two diets (control or hypercaloric [30% fat]). Systolic blood pressure was measured at day 175 and following infusion with 3 microg/g per day recombinant human IGF-1 (rh-IGF-I) by minipump for 14 d. Before treatment, UN offspring were hyperinsulinemic, hyperleptinemic, hyperphagic, obese, and hypertensive on both diets, compared with ad libitum offspring and this was exacerbated by hypercaloric nutrition. IGF-I treatment increased body weight in all treated animals. However, systolic blood pressure, food intake, retroperitoneal and gonadal fat pad weights, and plasma leptin and insulin concentrations were markedly reduced with IGF-I treatment. IGF-I treatment resulted in a 3- to 5-fold increase in 38--44 kDa and 28--30 kDa IGF binding proteins, although in UN animals, there was an impaired and differential up-regulation of these insulin-like growth factor binding proteins following IGF-I treatment. The 24-kDa IGF binding protein representing IGF binding protein-4 was down-regulated in all IGF-I-treated animals, but the decrease was more marked in UN animals. Our data suggest that IGF-I treatment alleviates hyperphagia, obesity, hyperinsulinemia, hyperleptinemia, and hypertension in rats programmed to develop the metabolic syndrome X.     

Differential expression, during the estrous cycle and pre- and postimplantation conceptus development, of messenger ribonucleic acids encoding components of the pig uterine insulin-like growth factor system.

The temporal patterns of endometrial expression for mRNAs encoding insulin-like growth factor-I (IGF-I), IGF-II, IGF-binding protein-2 (IGFBP-2), and the type I IGF receptor (IGF-IR) were elucidated in cyclic and pregnant pigs. Peak levels of IGF-I mRNAs occurred on day 12 in cyclic and early pregnant gilts, while IGFBP-2 mRNA levels were lowest on day 10. Pregnant gilt endometrium had higher levels of both RNA classes than the corresponding cyclic endometrium. IGF-II and IGF-IR mRNAs remained low during this period. In pregnant pig endometrium and rat uterus, levels of IGF-I mRNA decreased, while those of IGF-II and IGFBP-2 mRNAs increased with stage of pregnancy. Decreased endometrial production of IGF-I mRNA during pregnancy paralleled that in the myometrium. IGF-II mRNA tissue abundance was placenta greater than endometrium greater than myometrium. In contrast, IGFBP-2 mRNA levels were higher in endometrium than in placenta and myometrium. Endometrial expression of IGF-II mRNAs was limited to surface and glandular epithelial cells; epithelial and stromal cells expressed IGFBP-2 mRNAs at comparable levels. Expression of IGF-IR mRNAs was low and did not change with pregnancy. The endometria of two breeds of pigs that exhibit different levels of prolificacy were also examined for IGF mRNAs. On day 12, endometrium from the Large White breed with high conceptus mortality had higher levels of IGF-II and IGFBP-2 mRNAs than did endometrium from the Meishan breed with low conceptus mortality. Expression of IGF-I mRNAs was higher in endometria of Meishan than Large White gilts on day 12. The differential expression of IGF mRNAs with stage of gestation and the correlation of relative ratios of IGF mRNAs with prolificacy during the critical period of maternal recognition of pregnancy suggest an important role(s) for IGFs in conceptus and fetal development.     

Impact of periconceptional undernutrition on adrenal growth and adrenal insulin-like growth factor and steroidogenic enzyme expression in the sheep fetus during early pregnancy

Periconceptional undernutrition (PCUN) results in an earlier prepartum activation of the pituitary-adrenal axis in twin compared with singleton fetuses. We have tested the hypotheses that the functional development of the fetal sheep adrenal is delayed in twins compared with singletons in early gestation and that PCUN accelerates adrenal growth and increases the expression of intraadrenal IGF-I and -II and cytochrome P450 17-hydroxylase (CYP17) as early as 55 d gestation. We have investigated the effect of PCUN in the ewe (restricted at 70% of control allowance, n=21; control, n=24) from at least 45 d before mating until d 7 after mating on maternal cortisol and progesterone concentrations, fetal adrenal weight, adrenal IGF-I, IGF-I receptor (IGF-IR), IGF-II, IGF-IIR, and CYP17 mRNA expression and placental 11beta-hydroxysteroid dehydrogenase-1 and -2 mRNA and protein expression at d 53-56 pregnancy. The relative weight of the fetal adrenal and adrenal IGF-I, IGF-IR, IGF-II, IGF-IIR, and CYP17 mRNA expression were lower in twin compared with singleton fetuses. In singleton fetuses of PCUN ewes, there was a loss of the relationship between adrenal IGF-II/IGF-IIR expression and either adrenal weight or CYP17 mRNA, which was present in controls. Similarly in twin fetuses, PCUN resulted in the loss of the relationships between adrenal weight and IGF-I expression and between adrenal CYP17 and IGF-II expression, which were present in controls. Our findings suggest that differences in the timing of the prepartum activation of the fetal adrenal in twins and singletons have their origins in early gestation and highlight the importance of the interaction between the periconceptional environment and embryo number in setting the growth trajectory of the fetal adrenal.     

Effect of Ethanol on Insulin-Like Growth Factor-II Release from Fetal Organs

This study examines the effect of ethanol (ETOH) exposure and nutrient restriction on the release of insulin-like growth factor (IGF)-II from 18- and 20-day explanted fetal organs. Fetuses were exposed to ETOH (E) in utero by feeding dams a 36% (calories derived from ETOH: 6.6% v/v) ETOH liquid diet. Control fetuses were offsprings of dams either pair-fed (P) a control liquid diet or ad libitum (A) fed a standard pelleted lab chow. Brain, heart, kidney, liver, lung, muscle, and placenta of fetuses from the same litter were pooled and explanted, and IGF-II concentration in explanted media was analyzed by radioimmunoassay. Maternal and fetal weights were determined during pregnancy and at sacrifice, respectively, to evaluate the influence of ETOH on growth. Both maternal and fetal weights were substantially reduced by ETOH on 18 and 20 days of gestation compared with both A and P controls. At 18 days of gestation, E fetuses (1.33 ± 0.03 g) weighed less than either A (1.47 ± 0.03 g) or P (1.54 ± 0.04 g) fetuses. By 20 days, A mean fetal weight (4.19 ± 0.23 g) was significantly greater than both P (3.74 ± 0.06 g) and E (3.28 ± 0.06 g) fetuses. IGF-II concentration in media from 18-day fetal explants was highest from E (brain, heart, liver, and placenta) and P tissues (kidney, lung, and muscle). IGF-II in media from A tissues (except placenta) was lower than both E and P levels. A significant difference between treatments occurred in heart. By 20 days, IGF-II levels were highest in media from all A tissues (except placenta). IGF-II in media from E tissues (except lung) was lower than those from P tissues. A significant difference between treatments occurred in the brain. With regard to the developmental pattern, IGF-II release generally increased between 18 and 20 days of gestation, with the greatest increases occurring in A tissues. Increased secretion by P tissues was greater than that by corresponding E tissues, and tended to follow the A trend. On the other hand, E brain, kidney, and placenta released only slightly more IGF-II at 20 days compared to 18 days, whereas E heart, liver, lung, and muscle released slightly less hormone. This study suggests that even moderate nutrient deprivation influences the pattern of IGF-II release from fetal organs, even though there is only a small decrease in overall body size. At the same level of nutrient deprivation, ETOH more dramatically alters both fetal weight and the pattern of IGF-II release. Because IGFs are autocrine/ paracrine factors that influence growth, differentiation, and function, the reduced availability of IGF-II may be one of the factors contributing to ETOH-induced growth retardation and impaired functional capacity of some organ systems.