The influence of gestational zinc deficiency on the fetal insulin-like growth factor axis in the rat.

The insulin-like growth factor (IGF) axis, a key regulator of embryonic growth and development, is exquisitely sensitive to the nutrient status of the animal. In addition to macronutrient deficiencies, zinc deficiency can impact the IGF axis. Gestational zinc deficiency is teratogenic, resulting in intrauterine growth retardation and structural abnormalities. The aim of this study was to investigate the effects of gestational zinc deficiency on the fetal IGF axis in a rat model. From gestation day (GD) 0.5, dams consumed zinc-deficient (ZD, 0.3 mg zinc/kg) or control (25 mg zinc/kg) diet ad libitum, while a third group of dams consumed the control diet in amounts equivalent to the food intake of the ZD dams (Paired group). On GD 19.5 fetal tissue, blood and amniotic fluid were collected. Fetal growth was significantly reduced by zinc deficiency compared with the Paired and Control groups. Fetuses from the Paired group were smaller compared with the Control, but only ZD fetuses had structural malformations. Amniotic fluid IGF-1 concentrations were significantly lower in the Paired group than in the ZD and Control groups. Plasma of ZD fetuses contained lower levels of IGF binding protein-1 when compared with fetuses in the Paired and Control groups. Fetal liver IGF-1 mRNA levels were lower in the ZD fetuses than in the Paired and Control fetuses. These observations suggest that differences in the fetal IGF axis between ZD and Paired groups contribute to the poor pregnancy outcome and enhanced fetal growth retardation observed with zinc deficiency.

The effects of marginal maternal vitamin A status on penta-brominated diphenyl ether mixture-induced alterations in maternal and conceptal vitamin A and fetal development in the Sprague Dawley rat.

BACKGROUND: Polybrominated diphenyl ether (PBDE) toxicity in rodents can be associated with disruptions in endocrine signaling. We previously reported that the penta-BDE mixture, DE-71, disrupts thyroid hormones and vitamin A metabolism in rats during lactation, and that this disruption is amplified in animals fed diets marginal in vitamin A. The ability of the DE-71 to disrupt vitamin A metabolism during the prenatal period has not been evaluated. While penta-BDE mixtures are not strong teratogens in pregnant animals fed standard commercial laboratory diets, we hypothesized that they could be teratogenic under conditions of marginal vitamin A status. METHODS: rats were fed diets containing 0.4 retinyl equivalents (RE, marginal) or 4.0 RE (adequate) of vitamin A per gram of diet. Pregnant animals were exposed to DE-71 (0, 6, 18, 60, or 120 mg/kg) from gestation days (GD) 6-11.5, or on GD 6-19.5. RESULTS: DE-71 treatment resulted in dose-responsive reductions in maternal thyroid hormone and markers of vitamin A metabolism, with the latter reduction amplified in marginal vitamin A dams. Fetuses from marginal vitamin A, DE-71-exposed dams exhibited a dose-responsive increase in liver retinol binding protein levels. DE-71 treatment did not result in gross malformations; however, consistent with our hypothesis, GD 20 fetal weights were lower, and skeletal ossification was less when DE-71 exposure occurred concomitant with a marginal vitamin A status. For several endpoints, observable effects were evident at the lowest dose tested, consistent with a dose-response trend. CONCLUSIONS: The results of this study support the concept that marginal vitamin A status enhances the disruptive effects of DE-71 during prenatal development.

Zinc deficiency-induced iron accumulation, a consequence of alterations in iron regulatory protein-binding activity, iron transporters, and iron storage proteins.

One consequence of zinc deficiency is an elevation in cell and tissue iron concentrations. To examine the mechanism(s) underlying this phenomenon, Swiss 3T3 cells were cultured in zinc-deficient (D, 0.5 microM zinc), zinc-supplemented (S, 50 microM zinc), or control (C, 4 microM zinc) media. After 24 h of culture, cells in the D group were characterized by a 50% decrease in intracellular zinc and a 35% increase in intracellular iron relative to cells in the S and C groups. The increase in cellular iron was associated with increased transferrin receptor 1 protein and mRNA levels and increased ferritin light chain expression. The divalent metal transporter 1(+)iron-responsive element isoform mRNA was decreased during zinc deficiency-induced iron accumulation. Examination of zinc-deficient cells revealed increased binding of iron regulatory protein 2 (IRP2) and decreased binding of IRP1 to a consensus iron-responsive element. The increased IRP2-binding activity in zinc-deficient cells coincided with an increased level of IRP2 protein. The accumulation of IRP2 protein was independent of zinc deficiency-induced intracellular nitric oxide production but was attenuated by the addition of the antioxidant N-acetylcysteine or ascorbate to the D medium. These data support the concept that zinc deficiency can result in alterations in iron transporter, storage, and regulatory proteins, which facilitate iron accumulation.

Polybrominated diphenyl ether (PBDE)-induced alterations in vitamin A and thyroid hormone concentrations in the rat during lactation and early postnatal development.

In experimental animals fed standard laboratory diets, penta-BDE mixtures can decrease circulating thyroid hormone and liver vitamin A concentrations. A substantial number of pregnant women and their children have marginal vitamin A status, potentially increasing their risk of adverse effects to penta-BDE exposure. The current study investigated the effects of maternal gestational and lactational penta-BDE exposure on thyroid hormone and vitamin A homeostasis in rats of sufficient vitamin A (VAS) or marginal vitamin A (VAM) status and their offspring. Dams were administered daily oral doses of 18 mg/kg DE-71 (a penta-BDE mixture) or a corn oil vehicle from gestation day 6 through lactation day (LD) 18. Thyroid hormone and vitamin A homeostasis were assessed in plasma and tissues of LD 19 dams and postnatal day (PND) 12, 18, and 31 pups. DE-71 exposure induced hepatomegaly in VAS and VAM pups at all timepoints and increased testes weights at PND 31. While liver vitamin A concentrations were low in DE-71 treated dams and pups, plasma retinol concentrations and plasma retinol binding protein levels were only low in VAM animals exposed to DE-71. DE-71 exposure lowered plasma thyroxine concentrations in VAS and VAM dams and pups. Plasma thyroid stimulating hormone concentrations were high in VAM dams exposed to DE-71, suggesting that marginal vitamin A status enhances the susceptibility to thyroid hormone axis disruption by DE-71. These results support the concept that marginal vitamin A status in pregnant women may increase the risk for PBDE-induced disruptions in vitamin A and thyroid hormone homeostasis.

Zinc deficiency-induced cell death.

Zinc deficiency is characterized by an attenuation of growth factor signaling pathways and an amplification of p53 pathways. This outcome is facilitated by hypo-phosphorylation of AKT and ERK secondary to zinc deficiency, which are permissive events to the activation of the intrinsic cell death pathway. Low zinc concentrations provide an environment that is also conducive to the production of reactive oxygen/reactive nitrogen species (ROS/RNS) and caspase activation. Additionally, during zinc deficiency endogenous survival pathways such as NF-kappaB are inhibited in their transactivation potential. The above factors contribute to the irreversible commitment of the zinc deficient cell to death.

Zinc influences the in vitro development of peri-implantation mouse embryos.

BACKGROUND: For humans, it is estimated that over 70% of concepti are lost during early development. In culture, mouse peri-implantation embryos can mimic development from the blastocyst to the egg cylinder stage of development, a period during which implantation occurs in vivo. We describe a novel application of this model to investigate nutritional factors that may influence this stage of development. We investigated the influence of zinc (Zn) deficiency on embryonic development at the time of embryo implantation. METHODS: Mouse blastocysts were cultured for 144 hr in low Zn, Zn-replete or control medium. RESULTS: Embryos developed normally when they were cultured in the control and Zn-replete media. Embryos cultured in the low Zn medium were significantly impaired in forming egg cylinder morphology. This was associated with a reduction in extraembryonic endoderm as determined by immunohistochemistry for markers of visceral and parietal endoderm and correlated with an increase in TUNEL positive cells in the low Zn group. There was no change in the frequency of cells positive for phosphorylated Histone H3, a marker for S-phase, indicating that an increase in apoptosis was primarily responsible for the smaller size and reduction in extraembryonic endoderm. The increased cell death was not associated with an increase in reactive oxygen species (ROS) detected by dichlorodihydrofluorescein staining. CONCLUSIONS: These data support an important role for Zn in promoting differentiation and cell survival in the early embryo and suggest that sub-optimal nutrition is an important factor that contributes to defects in primary germ layers and early embryonic loss.

Developmental consequences of trace mineral deficiencies in rodents: acute and long-term effects.

Approximately 3% of infants born have at least one serious congenital malformation. In the U.S., an average of 10 infants per thousand die before 1 y of life; about half of these deaths can be attributed to birth defects, low birth weight or prematurity. Although the causes of developmental abnormalities are clearly multifactorial in nature, we suggest that a common factor contributing to the occurrence of developmental abnormalities is suboptimal mineral nutrition during embryonic and fetal development. Using zinc and copper as examples, evidence is presented that nutritional deficiencies can rapidly affect the developing conceptus and result in gross structural abnormalities. Deficits of zinc or copper can result in rapid changes in cellular redox balance, tissue oxidative stress, inappropriate patterns of cell death, alterations in the migration of neural crest cells and changes in the expression of key patterning genes. In addition to well-recognized malformations, mineral deficiencies during perinatal development can result in behavioral, immunological and biochemical abnormalities that persist into adulthood. Although these persistent defects can in part be attributed to subtle morphological abnormalities, in other cases they may be secondary to epigenetic or developmental changes in DNA methylation patterns. Epigenetic defects combined with subtle morphological abnormalities can influence an individual's risk for certain chronic diseases and thus influence his or her risk for morbidity and mortality later in life.

The plausibility of micronutrient deficiencies being a significant contributing factor to the occurrence of pregnancy complications.

Numerous studies support the concept that a major cause of pregnancy complications can be suboptimal embryonic and fetal nutrition. Although the negative effects of diets low in energy on pregnancy outcome are well documented, less clear are the effects of diets that are low in one or more essential micronutrients. However, several observational and intervention studies suggest that diets low in essential vitamins and minerals can pose a significant reproductive risk in diverse human populations. Although maternal nutritional deficiencies typically occur as a result of low dietary intakes of essential nutrients, nutritional deficiencies at the level of the conceptus can arise through multiple mechanisms. Evidence from experimental animals supports the concept that in addition to primary deficiencies, secondary embryonic and fetal nutritional deficiencies can be caused by diverse factors including genetics, maternal disease, toxicant insults and physiological stressors that can trigger a maternal acute phase response. These secondary responses may be significant contributors to the occurrence of birth defects. An implication of the above is that the frequency and severity of pregnancy complications may be reduced through an improvement in the micronutrient status of the mother.

Requirement for Foxd3 in maintaining pluripotent cells of the early mouse embryo.

Critical to our understanding of the developmental potential of stem cells and subsequent control of their differentiation in vitro and in vivo is a thorough understanding of the genes that control stem cell fate. Here, we report that Foxd3, a member of the forkhead family of transcriptional regulators, is required for maintenance of embryonic cells of the early mouse embryo. Foxd3-/- embryos die after implantation at approximately 6.5 days postcoitum with a loss of epiblast cells, expansion of proximal extraembryonic tissues, and a distal, mislocalized anterior organizing center. Moreover, it has not been possible to establish Foxd3-/- ES cell lines or to generate Foxd3-/- teratocarcinomas. Chimera analysis reveals that Foxd3 function is required in the epiblast and that Foxd3-/- embryos can be rescued by a small number of wild-type cells. Foxd3-/- mutant blastocysts appear morphologically normal and express Oct4, Sox2, and Fgf4, but when placed in vitro the inner cell mass initially proliferates and then fails to expand even when Fgf4 is added. These results establish Foxd3 as a factor required for the maintenance of progenitor cells in the mammalian embryo.