Retardation of fetal brain cell growth during maternal starvation: circulating factors versus altered cellular response

Adaptive Changes in Glucose Homeostasis and Islet Function During Pregnancy: A Targeted Metabolomics Study in Mice

OBJECTIVE

Pregnancy is a dynamic state involving multiple metabolic adaptions in various tissues including the endocrine pancreas. However, a detailed characterization of the maternal islet metabolome in relation to islet function and the ambient circulating metabolome during pregnancy has not been established.

METHODS

A timed-pregnancy mouse model was studied, and age-matched non-pregnant mice were used as controls. Targeted metabolomics was applied to fasting plasma and purified islets during each trimester of pregnancy. Glucose homeostasis and islet function was assessed. Bioinformatic analyses were performed to reveal the metabolic adaptive changes in plasma and islets, and to identify key metabolic pathways associated with pregnancy.

RESULTS

Fasting glucose and insulin were found to be significantly lower in pregnant mice compared to non-pregnant controls, throughout the gestational period. Additionally, pregnant mice had superior glucose excursions and greater insulin response to an oral glucose tolerance test. Interestingly, both alpha and beta cell proliferation were significantly enhanced in early to mid-pregnancy, leading to significantly increased islet size seen in mid to late gestation. When comparing the plasma metabolome of pregnant and non-pregnant mice, phospholipid and fatty acid metabolism pathways were found to be upregulated throughout pregnancy, whereas amino acid metabolism initially decreased in early through mid pregnancy, but then increased in late pregnancy. Conversely, in islets, amino acid metabolism was consistently enriched throughout pregnancy, with glycerophospholid and fatty acid metabolism was only upregulated in late pregnancy. Specific amino acids (glutamate, valine) and lipids (acyl-alkyl-PC, diacyl-PC, and sphingomyelin) were found to be significantly differentially expressed in islets of the pregnant mice compared to controls, which was possibly linked to enhanced insulin secretion and islet proliferation.

CONCLUSION

Beta cell proliferation and function are elevated during pregnancy, and this is coupled to the enrichment of islet metabolites and metabolic pathways primarily associated with amino acid and glycerophospholipid metabolism. This study provides insight into metabolic adaptive changes in glucose homeostasis and islet function seen during pregnancy, which will provide a molecular rationale to further explore the regulation of maternal metabolism to avoid the onset of pregnancy disorders, including gestational diabetes.

Early magnetic resonance imaging biomarkers of schizophrenia spectrum disorders: Toward a fetal imaging perspective

There is mounting evidence to implicate the intrauterine environment as the initial pathogenic stage for neuropsychiatric disease. Recent developments in magnetic resonance imaging technology are making a multimodal analysis of the fetal central nervous system a reality, allowing analysis of structural and functional parameters. Exposures to a range of pertinent risk factors whether preconception or in utero can now be indexed using imaging techniques within the fetus' physiological environment. This approach may determine the first "hit" required for diseases that do not become clinically manifest until adulthood, and which only have subtle clinical markers during childhood and adolescence. A robust characterization of a "multi-hit" hypothesis may necessitate a longitudinal birth cohort; within this investigative paradigm, the full range of genetic and environmental risk factors can be assessed for their impact on the early developing brain. This will lay the foundation for the identification of novel biomarkers and the ability to devise methods for early risk stratification and disease prevention. However, these early markers must be followed over time: first, to account for neural plasticity, and second, to assess the effects of postnatal exposures that continue to drive the individual toward disease. We explore these issues using the schizophrenia spectrum disorders as an illustrative paradigm. However, given the potential richness of fetal magnetic resonance imaging, and the likely overlap of biomarkers, these concepts may extend to a range of neuropsychiatric conditions.

Metabolic Adaptations in Pregnancy: A Review

BACKGROUND

Pregnancy is a dynamic state involving multiple adaptations that are necessary in order to ensure a continuous supply of essential metabolites to support the growth and the development of the fetus.

OBJECTIVES

This review article is aimed to discuss important adaptations in metabolism that take place during non-complicated pregnancy.

MATERIALS AND METHODS

We searched the electronic database PubMed for pre-clinical as well as clinical controlled trials reporting the importance of metabolic adaptations during a non-complicated pregnancy. The preferred language was English and the most recent reports were selected to get an updated review.

RESULTS

It was observed clearly in the searched literature that metabolic adaptations are a crucial part of pregnancy, as they provide the mother with sufficient energy stores to meet the demands of pregnancy. These adaptions also help in preparing the mother for lactation and also help in providing proper environment for the proper growth of fetus in the womb. Moreover, multiple biomolecules including glucose, fatty acids, ketone bodies, hormones collectively contribute toward these metabolic adaptations.

CONCLUSIONS

This review article concludes that metabolic adaptations are crucial for proper fetus development.

Thrombopoietin and the TPO receptorduring platelet storage

BACKGROUND

For most cells, the addition of a specific growth factor has improved cellular viability by preventing programmed cell death (apoptosis). To determine whether the platelet-specific hematopoietic growth factor thrombopoietin (TPO) might improve platelet viability, endogenous TPO and the platelet TPO receptor were analyzed during storage, and the effect of recombinant TPO on platelet viability was assessed.

STUDY DESIGN AND METHODS

During platelet storage, TPO stability was assessed by SDS-PAGE, TPO receptor function was measured, and the platelet TPO receptor was characterized by a (125)I-rHuTPO competitive-binding assay. A recombinant TPO, pegylated recombinant human megakaryocyte growth and development factor (PEG-rHuMGDF), was added to platelet concentrates during storage, and its effect on pH, LDH, and metabolic activity was determined.

RESULTS

During storage, the molecular weight and concentration of endogenous TPO (125 +/- 19 pg/mL) and exogenous TPO (5720 +/- 140 pg/mL) were constant for 12 days; the number (33 +/- 4), binding affinity (149 +/- 33 pM), and function of the platelet TPO receptors were constant for 7 days. Metabolic activity measured with the MTT and MTS assays closely correlated with changes in the pH and LDH. The addition of PEG-rHuMGDF did not alter the pH, LDH, or metabolic activity of platelets during storage, but it did increase by 65 percent the uptake of (35)S-methionine into platelets. Finally, platelet concentrates obtained from donors treated with PEG-rHuMGDF retained normal metabolic activity for 12 days, as compared with 5 to 6 days for normal platelet concentrates.

CONCLUSIONS

TPO and its platelet receptor are present in normal amounts and have normal function during platelet storage. The addition of recombinant TPO increased platelet methionine transport but did not alter platelet viability during storage. Other means to prevent apoptosis during platelet storage should be considered, and the measurement of platelet metabolic activity by MTT and MTS assays may assist this effort.

Alteration in IGF-I binding in the cerebral cortex and cerebellum of neonatal rats during protein-calorie malnutrition

Neonatal brain development in the rat is adversely affected by malnutrition. Alterations in tissue binding of IGF-I in the malnourished brain were tested in rat pups from mothers who were fed a 20% protein diet (C) or a 4% protein diet (M) starting from day 21 of gestation and continued throughout suckling. IGF-I binding in both cortex and cerebellum decreased progressively in C and M groups from day 6 to day 13. At day 9, 11, and 13, the binding was significantly greater (p < 0.02) in M compared to C groups. To investigate whether these changes might be related to the alteration in receptor activity, membranes were incubated with 125I-IGF in the presence of excess insulin with or without unlabeled IGF-I. In the absence of insulin, specific IGF-I binding in the M group was increased by 41.8 +/- 13.8% (mean +/- SEM p < 0.05) relative to C group. Insulin produced a consistent but incomplete inhibition of binding in both C and M, of 75% and 67% respectively. In addition, the specific IGF-I binding in the presence of insulin was increased in M group by 70.2 +/- 9.4% relative to C, p < 0.05. To characterize the nature of this binding, cerebral cortical membranes, from both groups, incubated with 125I-IGF-I were cross-linked, and electrophoresed on 6% and 10% SDS-PAGE gels under reducing conditions. Autoradiography of the 6% gel showed two specific bands at 115 kD and 240 kD, consistent with monomeric and dimeric forms of the IGF-I receptor, which were inhibited by excess insulin. In contrast, a 10% gel showed an additional band at 35 kD (IGF-binding protein) that was not inhibited by insulin. In both gels, membrane preparations from the M group showed a heightened intensity of the bands relative to C. The increase in binding protein relative to the receptor suggests a disequilibrium that may limit the availability of exogenous IGF-I to the tissues.

Proliferative growth of neonatal cerebellar cells in culture: regulation by male and by maternal serum in late gestation

Neonatal cerebellar cells were utilized as a model system to examine the effect of 20 day pregnant rat serum on proliferative growth in the CNS. Cells were prepared by mechanical dissociation and cultured as mixed cells or populations enriched in astrocytes or oligodendrocytes. Cell proliferation was estimated by measurement of DNA, protein, and/or mitochondrial reductase activity (MTT). When mixed cells were incubated with 10% male rat serum, both total DNA and protein content increased after 6 days of culture. By contrast, neither of these parameters were altered in cultures incubated with 10% pregnant serum. When cells were incubated with either male or pregnant sera, changes in MTT activity paralleled changes in protein content. Graded concentrations of pregnant serum (5-20%) added to mixed cell cultures produced consistently lower MTT values when compared with identical concentrations of male serum. In addition, MTT activity was diminished in both astrocytes and oligodendrocytes incubated with graded concentrations of pregnant sera when compared with similar concentrations of non-pregnant sera. When potential effects of these different sera on the cell cycle were examined, an increase in the number of cells in the S and G2/M phase was similar, and DNA doubling began to increase at 96 hrs in the presence of either male or 20 day pregnant sera. Thus the inhibition of cell growth by pregnant serum was not likely a result of either cytotoxicity or a delay of entry of cells into the cell cycle. To examine whether this inhibition of cell growth may reflect the effect of pregnant serum on endogenous growth factor production, we tested the production of IGF-II by cerebellar cells. production of an endogenous source of IGF-II was apparent using an RNAse protection assay and was noted using Slot Blot analysis of mRNA extracted at sequential times during cell incubation. Mixed cell cultures also secreted immunologically defined IGF-II. These observations are consistent with the previous demonstration that the fraction of pregnant serum which bound IGF-II also inhibited cell growth. The inhibitory effect of pregnant serum was diminished by preincubating aliquots of sera with graded concentrations of IGF-I prior to adding sera to tissue culture medium. Pregnant serum inhibition was also diminished by prolonging incubation times beyond 6 days. The blunting of pregnant serum inhibition may have been consequent to either a continuing production of endogenous growth factors or to the potential emergence of resistant cells due to prolonged tissue culture incubation.(ABSTRACT TRUNCATED AT 400 WORDS)

Insulin-like growth factor-I and binding protein-1 can modulate fetal brain cell growth during maternal starvation

1. Stimulation of brain cell growth by fetal plasma is reduced when levels of IGF-I are low and IGFBP-1 are high. 2. Fetal brain cells respond to IGFs in cell culture, and effects of plasma are reduced by addition of IGFBP-1. 3. Increased levels of IGFBP-1 and reduced availability of IGF-I may contribute to reduced brain growth when maternal nutrition is impaired.

Insulin-like growth factors and binding proteins in the fetal rat: alterations during maternal starvation and effects in fetal brain cell culture

Maternal malnutrition adversely affects fetal body and brain growth during late gestation. We utilized a fetal brain cell culture model to examine whether alternations in circulating factors may contribute to reduce brain growth during maternal starvation; we then used specific immunoassay and western blotting techniques, and purified peptides to investigate the potential role that altered levels of insulin-like growth factors (IGFs) and IGF binding proteins (IGFBPs) may play in impaired growth during maternal nutritional restriction. Fetal, body, liver, and brain weight were reduced after 72 hr maternal starvation, and plasma from starved fetuses were less potent than fed fetal plasma in stimulating brain cell growth. Circulating levels of IGF-I were reduced in starved compared to fed fetuses, while levels of IGF-II were similar in both groups. In contrast, [125I]-IGF-I binding assay demonstrated an increase in the availability of plasma IGFBPs following starvation. Western ligand blotting and densitometry indicated that levels of 32 Kd IGFBPs were 2-fold higher in starved compared to fed fetal plasma. Immunoblotting and immunoprecipitation with antiserum against rat IGFBP-1 confirmed that heightened levels of immunoreactive IGFBP-1 accounted for the increase in 32 Kd IGFBPs in starved plasma. Levels of 34 Kd BPs, representing IGFBP-2, were unaffected by starvation. Reconstitution experiments in cell culture showed that IGF-I promoted fetal brain cell growth, and that when they were supplemented with IGF-I, the growth promoting activity of starved fetal plasma was restored to fed levels. These changes were measured using MTT to assess mitochondrial reductase activity.(ABSTRACT TRUNCATED AT 250 WORDS)