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Effect of Hyperglycemia on Gene Expression during Early Organogenesis in Mice

  • Jing Zhao,

    Affiliation Tytgat Institute for Liver and Intestinal Research, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Theodorus B. M. Hakvoort,

    Affiliation Tytgat Institute for Liver and Intestinal Research, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • A. Marcel Willemsen,

    Affiliation Bioinformatics Laboratory, Department of Bioinformatics, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Aldo Jongejan,

    Affiliation Bioinformatics Laboratory, Department of Bioinformatics, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Milka Sokolovic,

    Affiliation Department of Biochemistry, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Edward J. Bradley,

    Affiliation Department of Genome Analysis, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Vincent C. J. de Boer,

    Affiliation Department of Laboratory Genetic Metabolic Diseases, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Frank Baas,

    Affiliation Department of Genome Analysis, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

  • Antoine H. C. van Kampen,

    Affiliations Bioinformatics Laboratory, Department of Bioinformatics, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands, Biosystems Data Analysis Group, University of Amsterdam, Amsterdam, The Netherlands

  • Wouter H. Lamers

    w.h.lamers@amc.uva.nl

    Affiliation Tytgat Institute for Liver and Intestinal Research, Academic Medical Center, University of Amsterdam, Amsterdam, The Netherlands

Abstract

Background

Cardiovascular and neural malformations are common sequels of diabetic pregnancies, but the underlying molecular mechanisms remain unknown. We hypothesized that maternal hyperglycemia would affect the embryos most shortly after the glucose-sensitive time window at embryonic day (ED) 7.5 in mice.

Methods

Mice were made diabetic with streptozotocin, treated with slow-release insulin implants and mated. Pregnancy aggravated hyperglycemia. Gene expression profiles were determined in ED8.5 and ED9.5 embryos from diabetic and control mice using Serial Analysis of Gene Expression and deep sequencing.

Results

Maternal hyperglycemia induced differential regulation of 1,024 and 2,148 unique functional genes on ED8.5 and ED9.5, respectively, mostly in downward direction. Pathway analysis showed that ED8.5 embryos suffered mainly from impaired cell proliferation, and ED9.5 embryos from impaired cytoskeletal remodeling and oxidative phosphorylation (all P ≤ E-5). A query of the Mouse Genome Database showed that 20–25% of the differentially expressed genes were caused by cardiovascular and/or neural malformations, if deficient. Despite high glucose levels in embryos with maternal hyperglycemia and a ~150-fold higher rate of ATP production from glycolysis than from oxidative phosphorylation on ED9.5, ATP production from both glycolysis and oxidative phosphorylation was reduced to ~70% of controls, implying a shortage of energy production in hyperglycemic embryos.

Conclusion

Maternal hyperglycemia suppressed cell proliferation during gastrulation and cytoskeletal remodeling during early organogenesis. 20–25% of the genes that were differentially regulated by hyperglycemia were associated with relevant congenital malformations. Unexpectedly, maternal hyperglycemia also endangered the energy supply of the embryo by suppressing its glycolytic capacity.

Introduction

Maternal diabetes is a well-established risk factor for congenital malformations in humans [1]. Among these, neural-tube and heart defects, kidney dysgenesis and the caudal regression syndrome are often reported [26]. The highest relative risk for major neural tube and cardiovascular defects occurs if the mother develops insulin resistance in the 1st trimester [7,8]. Similar phenomena have been reproduced in rodent models of diabetic pregnancy [9,10]. The animal studies showed that altered expression of genes that regulate the migration of neural crest cells and neural plate closure resulted in patterning defects of the developing head, neural tube and heart [11,12]. In vitro studies further showed that a high glucose concentration impaired the proliferation and cell-fate specification of neural stem cells [13].

In mice, ED7.5 appears to be the most sensitive time window for inducing congenital malformations of the neural tube: hyperglycemia at solely this time point suffices to induce these malformations [14,15]. Probably because congenital malformations associated with diabetic embryopathy manifest themselves only on ED10.5, inventories of hyperglycemia-induced changes in gene expression in the embryo were established on ED10.5 [16,17], ED11.5 [18], and between ED13.5 and ED15.5 [19]. These studies showed that maternal hyperglycemia affected the expression of genes involved in apoptosis, proliferation, migration and differentiation during organogenesis in the offspring. It is, however, conceivable that these inventories describe the sequels rather than the targets of the hyperglycemia-induced disturbance in metabolism, because neural-tube formation and neural-crest migration to the heart are initiated during the 8th embryonic day, that is, much earlier [20,21]. We, therefore, analyzed gene expression profiles in embryos of diabetic and nondiabetic pregnancies on ED8.5 and 9.5, that is, shortly after the embryos became sensitive to the hyperglycemia.

Our mouse model of diabetic pregnancy is based on that developed by Loeken [11]. In this elegant model, a moderate dose of streptozotocin (STZ) is used to induce diabetes. After 4–6 weeks of treatment, female mice were exposed to male mice. Because STZ has a very short half-life at neutral pH [22] and because oocytes do not replicate their DNA before fertilization, STZ itself probably has no mutagenic effects on the offspring. Moreover, the effects of STZ can be largely annulled if the STZ-treated mice are also treated with the immunosuppressive drug mycophenolate mofetil [23], suggesting that STZ induces an autoimmune response rather than cytotoxicity. Since the females are not yet severely hyperglycemic at conception, the protocol also avoids the adverse effects of severe maternal diabetes on the growth and maturation of preovulatory oocytes and preimplantation embryos [24]. In fact, severe hyperglycemia develops only after implantation of the embryos at ED4.5, which mimics pregnancy-induced diabetes in humans.

We made an inventory hyperglycemia-induced changes in gene expression in the embryo by creating a Serial Analysis of Gene Expression (SAGE) library and quantifying the mRNA distribution with SOLiD SAGE sequencing [25,26]. Bioinformatic analyses were then used to identify differentially expressed genes to delineate highly regulated pathways and cell-biological processes that were associated with diabetic embryopathy and, finally, to test whether the identified genes and pathways were, if deficient, responsible for neural tube or cardiovascular malformations. We found that that the expression of genes involved in the regulation of cell proliferation, cytoskeletal remodeling, and energy metabolism were most severely affected in ED8.5 and 9.5 embryos. Among the affected genes, many were previously shown to be responsible for neural tube or heart develop, and often for both.

Materials and Methods

Animals

FVB mice (9–11 weeks old) were obtained from Harlan Sprague Dawley (Venray, The Netherlands) and fed a diet that was based on Purina 9F (http://www.labdiet.com/cs/groups/lolweb/@labdiet/documents/web_content/mdrf/mdi4/~edisp/ducm04_028438.pdf; production: ABDiets, Woerden, The Netherlands). Mice were kept in groups of 4–5 mice in open cages at the animal facility, on a 12-h light/12-h dark cycle at 22°C with free access to water and food. The study was carried out in accordance with the Dutch Guidelines for the Care and Use of Laboratory Animals and approved by the Ethical Committee for Animal Research of the University of Amsterdam (ALC101225).

Induction of diabetes

The pregnant diabetic mouse model was adopted from Loeken c.s. [11]. This model has been extensively evaluated with respect to the malformations it induces in the central-nervous (CNS) and cardiovascular systems of the offspring. Diabetes was induced as recommended by the Animal Models of Diabetic Complications Consortium (AMDCC; [27]). Animals to be treated with streptozotocin were randomly chosen. The diabetic group included 33 and the control group 16 mice. 4–5 diabetic and control mice were housed in one cage. Prior to treatment, female mice were fasted for 6 hours. Sixty mg/kg streptozotocin (STZ; Sigma, Zwijndrecht, The Netherlands), freshly dissolved in 0.1 M sodium citrate (pH 4.5), was injected intraperitoneally for 5 successive days. Mice were screened for glucosuria with KETO-DIABUR-TEST 5000 test strips (Roche, Almere, The Netherlands) from 6 days after the first injection of STZ onwards. Body weight was checked twice weekly. Blood glucose levels were measured before the first injection of STZ and 3 weeks thereafter with a Glucometer Elite (Bayer, Mijdrecht, The Netherlands). Hyperglycemia was treated with subcutaneous sustained-release insulin implants (“linbits”; LinSHIN, Toronto, Canada) that release ~0.1 U/day*implant for at least 30 days. Depending on whether the concentration of blood glucose was 20–25, 25–30, or >30 mmol/L, 1, 1.5, or 2 linbits were implanted. Thereafter, blood glucose was measured weekly. STZ-treated female mice lost ~10% of their body weight in the first 3 weeks after treatment, but regained it upon treatment with the insulin implants (S1 Fig). STZ-treated mice without insulin supplementation were not included in the study. Two-to-three weeks after linbit implantation, mice that maintained glucose levels within the 10–15 mmol/L range were mated with nondiabetic male FVB mice. Noon of the day on which a copulation plug was found was set as embryonic day (ED) 0.5. Only pregnant females with blood glucose levels >17 mmol/L at ED7.5 were included in the experiment (~15 mmol/L is a critical value to induce hyperglycemic damage in embryos [15,28,29]). Pregnant mice were anesthetized with CO2 and then sacrificed by cervical dislocation and embryos were recovered between ED7.5 and ED11.5. The developmental stage of the embryos was checked with the criteria of Kaufman [30] (see S1 Table). Only embryos at the proper developmental stage were included in the study.

Quantification of mRNAs by SOLiD SAGE sequencing

Since we did not have an estimate of the variance in gene expression in our experimental animals, we relied on an approximation [31]. Based on a power of 0.8 and a false discovery rate (FDR) of 0.05, ≥8 arrays, that is, ≥8 embryos per time point and treatment should give informative results [31]. Therefore, 8 male diabetic and 8 male control embryos were randomly chosen from the collection for RNA isolation and SAGE analysis. Total RNA was extracted from the anterior half of embryos (transverse cut made just caudal to the heart) on ED8.5 and from the thoracic segment on ED9.5 (transverse cut made anteriorly between head and thorax, and posteriorly just caudal to the heart), using the TriPure Isolation Reagent (Roche, Almere, The Netherlands). Embryos were frozen and thawed 3 times using liquid nitrogen. After centrifugation, the organic phase of the TriPure extract was re-extracted 3 times. The combined aqueous phases were extracted with choloroform:isoamyl alcohol (24:1) and precipitated with ethanol after addition of 10 μg glycogen. The quantity of total RNA was determined with Qubit 1.0 Fluorometer (Invitrogen, The Netherlands), while the quality was assessed with the Bioanalyser RNA 6000 Nano Chip (Agilent Technologies, Amstelveen, The Netherlands). The RNA integrity number (RIN) of the samples was 9.0–10.0. The total RNA yield per embryo was 0.8±0.1 μg on ED8.5 and 1.8±0.3 μg on ED9.5.

The relative abundance of individual mRNAs was determined by the SOLiD SAGE approach. A double-stranded cDNA library was prepared from at least 0.5 μg RNA, using the SOLiD SAGE Sequencing kit with the Barcoding Adaptor Module (Applied Biosystems, Bleiswijk, The Netherlands; catalog #4452811) and the “working with small amounts of total RNA (1–2 μg)” protocol [26]. Polyadenylated mRNAs were captured with oligo(dT) Dynabeads (Invitrogen; supplied in the kit) and converted to cDNA while attached to the beads. After second-strand synthesis, the cDNA was cleaved with NlaIII. An adapter containing an EcoP15I-recognition site was ligated to the 5’end of the fragment still attached to the bead. EcoP15I cleaves DNA 25–27 bp downstream and releases a tag with a 2-bp overhang. After ligating another adaptor to this overhang, the tag was amplified as described (http://tools.lifetechnologies.com/content/sfs/manuals/cms_084611.pdf). This protocol generates only 1 read per mRNA molecule.

The amplified cDNA libraries, each with a specific barcode introduced during PCR amplification, were pooled in equal ratios. Size and concentration of the libraries were determined using the Bioanalyser DNA-1000 or high-sensitivity chip (Agilent Technologies, Amstelveen, The Netherlands). After affinity selection on beads, the pooled libraries were amplified by emulsion PCR to >30,000 copies, followed by further enrichment on beads and purification as described in SOLiD 4 System Templated Bead Preparation Guide. High-throughput sequencing was carried out on a SOLiD 5 system (Applied Biosystems, Bleiswijk, The Netherlands). The sequencing data are available at NCBI (accession number: PRJNA275285; SRA study: SRP056150).

To generate pure reads for analysis, adaptors were removed with Pyrodigm trimming [32]. Alignment was done with the “Burrows-Wheeler aligner” (BWA) against the Mus musculus reference genome “mm10”. More specifically, the BWA-backtrack algorithm, which is designed for sequence reads up to 100bp, was used [33]. The DESeq2 package (available through Bioconductor [34]) was used to analyze differential gene expression. Normalization for number of reads per embryo was performed using the “Estimate Size Factors” in the DESeq2 package. P-values were adjusted for multiple testing using the Benjamini-Hochberg procedure. A Padj < 0.05 was considered statistically significant. Clusters were generated with generalized linear models (GLM) based on expression patterns of top 100 genes ranked by P value. Pathway analysis with MetaCore software (GeneGo, Inc., St. Joseph, MI, USA) was used to assess the significance of changes in gene expression in specified pathways [35,36]. The significance was based on the degree of overlap between the user’s dataset and a set of genes corresponding to a network or pathway queried, assuming the probability that randomly obtained overlaps of a certain size between the user’s set and a network or pathway follow a hypergeometric distribution [37]. MetaCore determines the degree of association of uploaded datasets with predefined pathways and expresses the similarity in P-values, with lower P-values being more relevant.

Quantitative PCR analysis of gene expression

Quantitative PCR was performed using a Lightcycler 2.0 with the Fast Start DNA Masterplus SYBR Green I kit (Roche, The Netherlands). Primers were designed by the Primer-BLAST tool from NCBI and supplied in S2 Table. cDNA synthesis were performed by gene-specific priming with 40 pmol gene-specific primer and 20 pmol 18S primer. cDNA was diluted 40 times before assaying mRNA expression and 1,000-fold more for 18S expression. Gene expression was normalized relative to the expression of Tor3a and 18S. Tor3a was selected as reference genes with the NormFinder software [38] from the SAGE expression data. The average expression of Tor3a and 18S was calculated for each of the genes separately and put at 100% before their relative presence in each of the samples was used for normalization.

Sex identification

DNA from the visceral yolk sacs of ED8.5 embryos, or the posterior part (cut made just caudal to the heart) of ED9.5 embryos was isolated with TriPure Isolation Reagent (Roche, Almere, The Netherlands). The tissues were taken from the remaining parts of the embryos after harvesting the anterior part (ED8.5) and heart-containing segment (ED9.5) for mRNA quantification (next section). The sex of the embryos was determined by a multiplex PCR amplification using primers to amplify the male-specific Sry gene and the autosomal Il3 gene for reference [39].

Rate of oxygen consumption and glycolysis

Real-time rates of cellular oxygen consumption (respiration) and proton excretion (glycolysis) in control and hyperglycemic ED9.5 embryo cells were determined using the Seahorse Extracellular Flux (XF-96) analyzer (Seahorse Bioscience, Billerica, MA). 5*104 freshly isolated embryonic cells were seeded in an XF microplate and cultured for 2 hours in the presence of 11.1 mmol/L D-glucose and 10% fetal bovine serum prior to measurement of the oxygen consumption rate (OCR) and extracellular acidification rates (ECAR). Sequential additions of the ATP synthase inhibitor oligomycin, the uncoupling ionophore carbonyl cyanide-p-trifluoromethoxyphenylhydrazone (FCCP), and the cytochrome-c-reductase inhibitor antimycin A were as per the manufacturer’s instructions and allowed determination of the basal rate of oxygen consumption (no additions), the rate of oxygen consumption linked to ATP production (oligomycin addition), the maximal respiration capacity (FCCP addition), and the rate of non-mitochondrial oxygen consumption (antimycin A). The ECAR was determined under basal conditions (no additions) and after inhibition of mitochondrial ATP synthesis with oligomycin. The number of cells was estimated as protein content, which was determined for each well using a standard BCA protein assay. OCR and ECAR values are normalized to mg protein and expressed as the mean ± SEM.

Data analysis

Gene expression is shown as mean ± SEM. The tests of glucose level and oxygen consumption and extracellular acidification measurements were performed by ANOVA or Student’s t-test. A P < 0.05 was considered statistically significant and < 0.1 as indicating a trend.

Results

1. The mouse model of diabetic pregnancy

In this study we investigated the effects of hyperglycemia on embryos in the early somite period, that is, on ED8.5 and ED9.5 (7–20 somites). The blood glucose levels in the dams from the induction of diabetes to sacrifice are shown in Fig 1. Blood glucose concentrations of female mice after induction of diabetes (P < 0.001), during the mating period (P < 0.01), and during pregnancy (P < 0.001) were significantly higher than those in controls. In diabetic mice, maternal blood glucose concentrations decreased to ~50% after the implantation of sustained-release insulin implants (“linbits”; P < 0.001), while maternal blood glucose concentrations rose markedly between mating and ED7.5 (P < 0.001) and between ED7.5 and 8.5 (P < 0.03), after which it plateaued (P8.5vs9.5 = 0.72, P9.5vs10.5 = 0.38 and P10.5vs11.5 = 0.28). Because human clinical studies showed that male offspring was more sensitive to the effect of maternal diabetes than female [40], male mouse embryos were investigated. All embryos in the study were alive and none was externally abnormal or delayed in development (S2 Fig).

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Fig 1. Blood glucose levels in pregnant diabetic mice.

Blood glucose levels were measured before streptozotocin (“preSTZ”) treatment, 3 weeks after the first STZ injection (“STZ”), on the day of mating (“mating”), on ED7.5 of pregnancy (“ED7.5”), and at sacrifice (“ED8.5-ED11.5”). After STZ treatment, blood glucose of diabetic mice increased to ~26 mmol/L. Insulin pellets (“linbit”) were implanted after establishing the diabetic state of the mice. Mating was performed when blood glucose was ~14 mmol/L. The control group was not treated with STZ or insulin. Differences between blood glucose levels of diabetic (n = 33) and control mice (n = 16) were analyzed by one-way ANOVA and t test. Filled symbols: non-diabetic control mice; open symbols: STZ-treated diabetic mice. **: P < 0.001 (comparison of blood glucose between STZ and mating, mating and ED7.5). *: P < 0.03 (ED7.5 vs ED8.5; ED8.5 did not differ from ED9.5-ED11.5).

https://doi.org/10.1371/journal.pone.0158035.g001

2. Global profile of gene expression in ED8.5 and 9.5 embryos

To obtain a comprehensive overview of the response of embryos to maternal hyperglycemia at an early developmental stage, whole transcriptome profiles of ED8.5 and ED9.5 embryos were investigated with SOLiD SAGE mRNA deep sequencing. To obtain a representative expression-profile library, construction had to be started with at least 0.5 μg mRNA to assure that the number of detected genes for a library was not dependent on the input of total RNA (S3 Fig). We obtained ~8*106 pure reads and the expression profile of ~2*104 genes per embryo.

The dendrogram generated by non-supervised hierarchical clustering with correlation as similarity measure and average linkage as clustering parameter revealed that maternal diabetes separated control and hyperglycemic groups into distinct branches on ED9.5 (Fig 2B), but not yet on ED8.5 (Fig 2A). The length of a branch reflects the degree of difference between samples. Of the 8 control and 8 hyperglycemic ED8.5 embryos that were analyzed, a subgroup of 3 control embryos clustered with the hyperglycemic embryos (Fig 2A). These differently behaving control embryos were from 2 litters that also had a member in the main control group. Furthermore, one hyperglycemic embryo behaved quite differently from the remaining embryos, because the input of mRNA for cDNA synthesis was too small (0.3 μg; no saturation in genes detected, see S3 Fig). To identify the regulated pathways on ED8.5, we performed pathway analysis on the 7 hyperglycemic and 5 control embryos that clustered together. Compared to the control group, 2305 (ED8.5) and 4640 (ED9.5) unique transcripts met our boundary condition for significance (Padj < 0.05) and were ≥ 1.5-fold up- or downregulated as a result of maternal diabetes. The log2 fold change distribution of differentially expressed genes (Padj < 0.05) in the entire population on ED8.5 and 9.5 is shown in Fig 3. The majority of these genes were down-regulated (~80% on ED8.5 and ~65% on ED9.5). After removal of RIKEN, EST, unassigned and hypothetical gene sequences, 1024 functional unique genes were changed in expression in ED8.5 and 2148 genes in ED9.5 hyperglycemic embryos (~45% of the original number on both days). Of the genes that were differentially expressed on ED8.5, ~85% was also differentially expressed on ED9.5 (Fig 4A), but represented only ~40% of all differentially expressed genes on that day, implying that the main difference between ED8.5 and ED9.5 was that the number rather than the identity of affected genes had expanded. A list of all differentially expressed genes on ED8.5 and ED9.5, and their fold change, can be found in S3 Table.

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Fig 2. Hierarchical clustering of the changes in gene expression in control and hyperglycemic ED8.5 and ED9.5 embryos.

Messenger RNA from control and hyperglycemic ED8.5 (left panel) and ED9.5 embryos (right panel) was extracted (8 embryos per group) and each used for the construction of a separate SOLiD SAGE library. “C” and “D” at the bottom margin of the panels indicate “control” and “diabetic” (hyperglycemic) embryos, respectively. Hierarchical clustering was performed by DESeq analysis. The dendrogram on the top of the panels reflects the correlation in differential gene expression between embryos, with less height indicating a higher similarity. The dendrograms at the left margin indicate the correlation in the response of the respective genes. The intensity of the blue color represents the relative level of expression of a gene (after transforming the data for variance stabilization). One ED8.5 hyperglycemic embryo was removed because the input of mRNA was low (< 0.5 μg) and subsequent output of mRNA too small (see S1 Fig). Three ED8.5 control embryos clustered with the hyperglycemic embryos and were not included in the analyses (see main text). At ED8.5, 2305 genes were differentially expressed (panel A; 7 hyperglycemic and 5 control embryos were compared). On ED9.5, 4640 were differentially expressed (panel B).

https://doi.org/10.1371/journal.pone.0158035.g002

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Fig 3. The distribution of the fold-change of differentially expressed genes in ED8.5 and 9.5 embryos.

Panels A and B show the fold-change of the 2305 and 4640 differentially expressed genes on ED8.5 and 9.5, respectively, with fold change ≥1.5, as detected after DESeq analysis. The X-axis shows bins with log2-fold change, while the Y-axis indicates the frequency of each event. Note that the majority of genes were downregulated in hyperglycemic embryos (~80% on ED8.5 and ~65% on ED9.5).

https://doi.org/10.1371/journal.pone.0158035.g003

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Fig 4. Genes differentially expressed in hyperglycemic ED8.5 and ED9.5 embryos associated with cardiovascular and/or neural defects.

Panel A: 1024 and 2148 were differentially expressed, unique functional genes in embryos from hyperglycemic and control dams on ED8.5 and 9.5, respectively, 876 of which were common to ED8.5 and ED9.5. The Jackson Laboratory Mouse Genome Database (MGD) at the Mouse Genome Informatics website (URL:http://www.informatics.jax.org; October 2014) was queried by selecting “Phenotypes & Mutant Alleles—Phenotypes, Alleles & Disease Models Query—Anatomical Systems Affected by Phenotypes” and searching with “Cardiovascular system”, “Nervous system” and “Embryogenesis” as key words (total number of genes retrieved: 3955). Panel B shows a Venn diagram of the number of genes associated with the respective categories in the MGD database. Of these genes, 131, 164 and 123 among the 1024 differentially expressed genes on ED8.5 (panel C), and 287, 362 and 243 out of 2148 genes on ED9.5 (panel D) were associated with cardiovascular, neural or embryogenesis defects, respectively.

https://doi.org/10.1371/journal.pone.0158035.g004

To validate the SAGE analysis, among 2148 unique differentially expressed genes on ED9.5, 11 down-regulated (Ndufa6, Actg1, Glut4, Fgf2, Tpm4, Marcksl1, Myosin1H, Axin1, Mrto4, Psmc4 and Ptpn11) and 4 up-regulated (Mrps23, Rnaseh2c, Cdk1 and Ubxn8) genes were selected for validation by quantitative PCR (qPCR). The prevalence ranged from rare to abundant. In addition, 11 genes without change in expression (Padj > 0.05 and fold-change ~1; Gtf3c2, Raf1, Tab2, Trip13, Atp5c1, Cdc20, Tor3a, Mtch1, Pax3, Bax and Arg1) were selected. Fig 5 shows the correlation of expression levels of these genes between SOLiD SAGE sequencing and qPCR in control embryos (the values and the color code of the symbols are shown in S4 Table). The range of expression across which this correlation was tested was ~103. Apart from 3 obvious outliers (Cdc20, Actg1, and Atp5c1), the expression as assayed by SAGE sequencing and qPCR correlated (R2 = 0.57). We have not been able to identify technical errors that could have accounted for the outliers.

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Fig 5. Correlation of mRNA expression levels analyzed by SOLiD SAGE sequencing and quantitative PCR analysis.

The mRNA of 8 euglycemic embryos on ED9.5 was quantified by SOLiD SAGE sequencing. Based on Padj (<0.05) and fold-change (>1.5) of differentially expressed genes in SOLiD SAGE sequencing, 11 genes without change, 4 up-regulated genes and 11 down-regulated genes were selected for validation by qPCR. The mRNA of 8 other euglycemic embryos on ED9.5 was quantified by qPCR after cDNA synthesis by gene-specific priming. The X-axis shows the number of reads after SOLiD SAGE sequencing and normalization for total reads in each embryo. The Y-axis indicates gene expression in qPCR normalized by the expression of reference genes Tor3a and 18S. The error bar indicates ± SEM.

https://doi.org/10.1371/journal.pone.0158035.g005

3. Pathways regulated by maternal hyperglycemia

Since a global analysis does not reveal a direction in the changes and lacks functional detail, we scrutinized the data for biological pathways with functional implications with MetaCore. The 2305 transcripts on ED8.5 and the 4640 transcripts on ED9.5 that were differentially expressed between embryos of hyperglycemic and control mice were analyze for linkage to pathways in the MetaCore suite. As shown in Table 1, the cell cycle and cell proliferation on ED8.5 (positions 1–3 and 8 on ED8.5; position 4 on ED9.5), cytoskeletal remodeling and cell adhesion on ED9.5 (positions 1, 2, 5, 7, and 9 on ED9.5; positions 4, 5, 7 and 9 on ED8.5), and oxidative phosphorylation (position 3 on ED9.5 and 6 on ED8.5) were very prominent among the top 10 highly regulated pathways that differ between hyperglycemic and control embryos on ED8.5 and 9.5 (all P ≤ E-5). The level of significance was higher on ED9.5, largely because more genes were affected. Taking into account that the cited regulated pathways often shared genes, the cell cycle was more prominently affected in hyperglycemic embryos on ED8.5 than ED9.5 (P value smaller on ED8.5 than ED9.5), whereas cytoskeleton remodeling, together with cell adhesion and migration, and oxidative phosphorylation became more vulnerable on ED9.5 (P value larger on ED8.5 than ED9.5). The suppression of oxidative phosphorylation by maternal hyperglycemia became more important on ED9.5 as deduced from the ~100-fold smaller P value on ED9.5 compared to ED8.5. Four pathways (oxidative phosphorylation, Wnt/TGFβ signaling, cytoskeleton remodeling (ephrin B), and cytoskeleton remodeling (remodeling), were highly regulated in both ED8.5 and ED9.5 embryos. On closer inspection, only 0%, 4%, 12%, and 19% of the 21, 16, 31 and 27 genes, respectively, that were differentially regulated in these pathways at ED8.5, were not present in the same pathways on ED9.5. Because the number of genes affected in these pathways increased 1.5–2.5-fold, this finding indicates that the number of affected genes in these pathways increased between ED8.5 and ED9.5 rather than the identity of the pathways involved.

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Table 1. Highly regulated pathways in ED8.5 and ED9.5 hyperglycemic embryos.

https://doi.org/10.1371/journal.pone.0158035.t001

4. Differentially expressed genes are involved in heart and/or neural-tube defects

To establish if the differentially expressed genes on ED8.5 and ED9.5 could account for heart or neural-tube defects if downregulated, we queried the Jackson Laboratory Mouse Genome Database (MGD; for protocol, see the legend of Fig 4). This database contains 3781 genes that, if deficient, cause cardiovascular defects, 5195 genes that cause neural (“cerebrospinal”) defects, and 2746 genes that have general effects on embryonic development (database queried in October 2014; Fig 4B). Among the 1024 genes that were present in the MGD and differentially expressed in hyperglycemic and control embryos on ED8.5, 131, 164 and 123 (6.8, 6.2, and 8.9% in each group) were related to defects in cardiovascular, neural, and general embryonic development (Fig 4C), respectively, while among the 2148 genes that were in the database and differentially expressed on ED9.5, 287, 362, and 243 (14.9, 13.7 and 17.6% in each group) were related to the respective defects (Fig 4D). Of the differentially expressed genes that were linked with cardiovascular or neural-tube defects, 23.3% was associated with both conditions on both ED8.5 and ED9.5 (~13.6% and ~16.9% were exclusively associated with cardiovascular and neural-tube defects, respectively, on both days (S4 Fig)). In total, 26% of the differentially expressed genes in either ED8.5 or ED9.5 hyperglycemic embryos were causally associated, if deficient, with cardiovascular or neural defects according to the MGD database (S5 Fig). Of the genes relevant to each defect that were identified on ED8.5, 85.5% was still present in the group of affected genes on ED9.5 (Fig 4A), again implying that the hyperglycemic condition of the embryos had aggravated their condition between ED8.5 and ED9.5.

It should be kept in mind that the MGD database describes the phenotype after complete inactivation of single genes, whereas a partial polygenic etiology is considered more likely. We, therefore, checked the number of genes that were >5-fold and >10-fold up- or downregulated on ED8.5 and ED9.5, and were associated with cardiovascular or neural malformations if absent (S5 Fig). On ED8.5, 217 and 55 genes were changed >5- and >10-fold, respectively, while on ED9.5, these numbers were 299 and 90, respectively. Of these, 23–24% and 4–5% were, if deficient, associated with congenital malformations on ED8.5 and ED9.5, respectively. A 10-fold reduction is what one reads in published knockdown experiments. Furthermore, the expression of almost all of them (~98%) was suppressed and at least some of the affected genes may well have acted synergistically.

The 106, 138 and 99 genes that were differentially expressed in hyperglycemic embryos on both ED8.5 and 9.5 in cardiovascular, neural and whole-embryonic developmental defects, respectively, were used for pathway analysis in MetaCore and found to be also mainly involved in cytoskeletal organization, including cell adhesion (P < 5E-5; not shown). This finding underscores that the pathways that were identified as being highly regulated by hyperglycemia in ED8.5 and ED9.5 embryos (Table 1) are very relevant for the malformations in the cardiovascular and neural systems that are observed in diabetic pregnancies. As already stated, a high percentage of these genes affected both cardiovascular and neural development (Fig 4).

5. Energy metabolism

The expression of genes involved in oxidative phosphorylation was strongly regulated in both ED8.5 and ED9.5 hyperglycemic embryos (Table 1). The expression of subunits of mitochondrial enzymes Cox8a (cytochrome c oxidase subunit 8A) and Atp5e (ATP synthase subunit) were, for example, >10-fold down-regulated, whereas Ndufa1 (NADH dehydrogenase subcomplex) was 5-fold up-regulated on ED9.5, all suggesting inhibition of mitochondrial respiration and adaptation to glycolytic flux. We anticipated that hyperglycemia would also affect the expression of glucose transporters. Fig 6 shows that Glut1, -2, and -3 (Slc2a1-3) were most highly expressed, but all 3 transporters showed a pronounced decrease in expression between ED7.5 and ED9.5, and were not affected by hyperglycemia, except for a trend for Glut3 (P = 0.08). In contrast, the insulin-responsive glucose transporters Glut4, -8, and -10 (Slc2a4, -8, and -10) were expressed to a much lower extent, but increased with development and, with the exception of Glut8, were negatively affected by hyperglycemia. Glut4 was most sensitive in this respect, with a ~5-fold decreased expression in hyperglycemic embryos. The expression of sodium-coupled glucose transporters was extremely low (not shown).

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Fig 6. Expression of glucose transporters in control and hyperglycemic embryos.

The most highly expressed glucose transporters (Glut1-3) all declined during normal development (ED7.5–9.5), whereas the insulin-regulated glucose transporters (Glut4, -8, and -10) increased in concentration (note that the Glut1-3 values are expressed after division by 1,000). Hyperglycemia had no (Glut1 and -2) or a small negative effect (Glut3 on ED8.5 only) on the highly expressed glucose transporters, but clearly suppressed two of the insulin-regulated transporters. Diamond symbols indicate the control group and square symbols the hyperglycemic group. P values compare expression between hyperglycemic and control embryos on the indicated day.

https://doi.org/10.1371/journal.pone.0158035.g006

To investigate whether these changes in gene expression reflected differences in mitochondrial function and/or glycolysis, we measured the rates of oxygen consumption and extracellular acidification in cells of control and hyperglycemic ED9.5 embryos. As shown in Fig 7, the rate of basal oxygen consumption in diabetic cells was ~85% of that in control cells (P = 0.03). No differences were observed after oligomycin, FCCP, and antimycin A addition, revealing that the maximal respiration capacity (FCCP addition) and the rate of non-mitochondrial oxygen consumption (antimycin A) were not different. Oxidative phosphorylation (basal OCR—oligomycin-suppressed OCR) in cells from control and hyperglycemic embryos were not different (68 ± 11 and 47 ± 10 pmol/min.mg protein, respectively (P = 0.19)). The extracellular acidification rate was significantly lower in cells from hyperglycemic than from control embryos (~70%; P = 0.01). Furthermore, glycolysis already functioned at the maximal rate under basal conditions, as the addition of oligomycin did not increase ECAR. In addition, these data show that ATP synthesis from glycolysis (~25 nmol/min.mg protein) in cells from control embryos is ~150-fold higher than that from oxidative phosphorylation (~0.17 nmol/min.mg protein; phosphate/oxygen ratio set at 2.5). Because both oxidative phosphorylation and glycolysis are ~30% lower in cells from hyperglycemic embryos, the ratio remains similar. These data show that glycolytic activity was the main source of energy production in ED9.5 embryos and that its activity and capacity was substantially lower in hyperglycemic embryos, indicating they had an energy problem.

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Fig 7. Oxygen consumption and extracellular acidification in cells of control and hyperglycemic embryos on ED9.5.

Cells obtained from 12 hyperglycemic and 17 control ED9.5 embryos were used to measure the rate of oxygen consumption (OCR; panel A) and extracellular acidification (ECAR; panel B). Gray bars represent cells from control and black bars from hyperglycemic embryos. The bars indicate the OCR and ECAR under basal conditions and after sequential addition of oligomycin, FCCP and antimycin A. Data represent 3 consecutive measurements of separate dishes with cells from 4 hyperglycemic embryos and 6 control embryos on average. The Y-axis indicates oxygen consumption (pmoles/min.mg protein) or extracellular acidification (mpH/min.mg protein). The asterisk indicates a significant difference between control and hyperglycemic embryos. **: P < 0.01. *: P = 0.03 (basal OCR control vs diabetic) and P = 0.01 (ECAR after treatment of oligomycin control vs diabetic).

https://doi.org/10.1371/journal.pone.0158035.g007

Discussion

Earlier studies on ED10.5–15.5 embryos showed that maternal hyperglycemia affects the expression of genes involved in apoptosis, proliferation, migration and differentiation [1619]. In the present study, we examined the effect of maternal hyperglycemia in mouse embryos during gastrulation and early organogenesis (ED8.5 and ED9.5). The main findings were that pregnancy aggravated hyperglycemia in mildly diabetic dams, as it does in humans [41], and that hyperglycemia in the embryo developed before the onset of insulin production and affected the expression of genes involved in the regulation of cell proliferation, cytoskeleton, and energy metabolism. Approximately 25% of the differentially regulated genes were associated with cardiovascular and neural malformations if deficient.

Hyperglycemia and glucose transport

Insulin (and glucagon) can be detected only in embryos with >20 somites (ED9.25) [42], and maternal insulin does not reach the embryo proper [43]. In agreement, our gene expression data do not show expression of the insulin-signaling factors Insr, Irs1/2, or Akt1 in ED8.5 or ED9.5 embryos (Pik3 is expressed). Embryonic hyperglycemia, therefore, most likely exerts its teratogenic effects in the absence of insulin, that is, directly on sensitive cells via glucose transporters or as osmolyte.

Although Glut1, -2, and -3 are mostly expressed in the extraembryonic tissues (yolk sac, amnion and/or ectoplacental cone) [44,45], expression of Glut1 and Glut3 in the embryo was >100-fold and that of Glut2 >10-fold higher than the other glucose transporters. Expression of these Gluts peaked, in agreement with literature [44,4649], during implantation and gastrulation, and declined in a pronounced manner after ED7.5 (Glut2, Glut3) or ED8.5 (Glut1). Also in agreement with literature [45,50,51], the expression of Glut1, -2, and -3 was not or only mildly affected by hyperglycemia. Since Glut2 deficiency appears to protect the embryo from the teratogenic effects of hyperglycemia [51], the pronounced decline of its expression after ED7.5 may explain the window of sensitivity to hyperglycemia around ED7.5 [15].

In contrast to Glut1, -2, and -3, the expression of Glut4 and Glut10 increased with development and was strongly suppressed by hyperglycemia. Expression of Glut4 in postimplantation embryos first appears in the yolk sac and ectoplacental cone, and then increasingly also in the embryonic tissues [48,52]. GLUT4, -8 and -10 are all recruited to the plasma membrane via an insulin-dependent increase in cytoskeletal actin polymerization [5355] and become expressed only when endogenous insulin production starts at ED9.5 [42]. The phenotype of Glut4- [56], Glut8-[57], or Glut10-deficient [58] embryos does not suggest a role for these transporters in hyperglycemic embryopathy, but it remains to be established whether the deficiency protects against the adverse effects of hyperglycemia in early development [59].

Hyperglycemia and the cytoskeleton

The cytoskeleton plays a prominent role in the changes in cell shape and the morphogenetic movements that characterize cell behavior during gastrulation and organogenesis [60,61]. Hyperglycemia suppresses the cell cycle [62] and causes a pronounced downregulation of the expression of many genes of key components of the cytoskeleton in embryos. Embryonic hyperglycemia suppressed the expression β- and especially γ-cytoskeletal actin, the cobblestones of the dynamic submembranous cytoskeletal network, ~3- and ~100-fold, respectively. The expression of associated small GTPases, including Rho, Cdc42, and Rac, and the ezrin, radixin, and moesin (ERM) proteins [63,64] was also affected. Exposure to glucose phosphorylates and activates Cdc42. Interaction of active Cdc42 with WASP receptors activates ARP2/3, which enhances actin nucleation and branching. Activated ARP 2/3, in turn, joins onto pre-existing microfilaments and creates a site for the extension of new microfilaments (branching). Cofilin, another downstream signal of Cdc42 and other members of the RHO family that is active in its dephosphorylated form, promotes actin depolymerization. Integrins or PKC are major activators of cofilin-1. The balance of N-WASP and cofilin activities determines the direction of cytoskeleton dynamics. Since the expression of virtually all these genes was affected, cytoskeletal dysfunction must be a prominent sequel of embryonic hyperglycemia. Hyperglycemia also enhances the depolymerization and polymerization cycle rate (“dynamic instability”) of cytoskeletal actin [63,65,66]. This post-translational effect of hyperglycemia appears to be mediated by the hyperosmotic stress it causes [67,68]. The highly significant and largely inhibitory effects of maternal diabetes on the structure and function of the cytoskeleton indicates that the teratological effects of embryonic hyperglycemia are at least in part mediated by this fairly general insult on cellular integrity.

Hyperglycemia and metabolism

The preimplantation embryo becomes exposed to hypoxic conditions when entering the uterus [69]. Coincident with the accompanying transition to glycolytic energy metabolism, the mitochondrial cristae become tubular and vesicular, while the reappearance of lamellation of the cristae during early organogenesis is a sign of mitochondrial maturation [7072]. In agreement, oxidative phosphorylation begins to contribute increasingly to energy metabolism after ED9.5 [73,74]. Embryonic hyperglycemia delays this maturation and induces mitochondrial swelling [75]. In agreement, we observed that maternal hyperglycemia suppressed the expression of many genes involved in mitochondrial function. Perhaps even more importantly, we showed that on ED9.5, glycolytic energy production at ED9.5 still accounts for ~99.5% of total energy production. To place this number in perspective, one has to realize that the oxygen consumption rate at ED9.5 was only ~1% of that of primary hepatocytes, while glycolysis measured as the rate of extracellular acidification exceeded that of primary hepatocytes by ~10-fold in experiments carried out in the same month on the same Seahorse analyzer (EH Gilglioni, unpublished data). These numbers demonstrate that glycolysis is still the predominant energy source at ED9.5 and that the ~30% decline in glycolytic activity and capacity deprived hyperglycemic ED9.5 embryos of a substantial share of their capacity to produce ATP. This finding contrasts with the prevalent hypothesis that the teratogenic effects of hyperglycemia have to be ascribed to the oxidative stress that arises from flooding the embryonic mitochondria with respiratory substrates [76,77], and/or to the activation of the hexosamine pathway and associated inhibition of NADPH regeneration[78], which would compromise the still poorly developed antioxidative defense [79].

Hyperglycemia and congenital malformations

The association of maternal diabetes and congenital malformations of the cardiovascular and neural systems is quite strong [2,5]. To demonstrate that some of the genes that are differentially regulated by hyperglycemia are indeed causally involved in the development of malformations, one has to interfere with their expression. In this respect, it should be kept in mind that the majority of genes were downregulated on both ED8.5 and ED9.5 (~80% on ED8.5 and 65% on ED9.5). We, therefore, queried the Jackson Laboratory MGD database of genes causing cardiovascular or neural if deficient. This query showed that 20–25% of the genes regulated by hyperglycemia have already been demonstrated to cause heart, neural-tube, or embryonic malformations if deficient. Almost one quarter of these genes are shared between heart and neural tube, in agreement with the fact that these malformations often co-occur [2,4,5]. A similar approach was carried out on ED10.5 embryos from hyperglycemic and control mice [16,17]. In this study, which focused on neural-tube defects, the genes that were affected by maternal diabetes and that caused malformations were far more often part of the Wnt, Hh, Notch, or MAPK signaling pathways than of the cytoskeletal network. These data suggest that the hyperglycemia-induced involvement of the cytoskeleton is no longer prominent at ED10.5. Similarly, the effect of hyperglycemia on mitochondrial structure reportedly disappears with age in the embryo [75].

Limitations of the Study

The choice of the animal model is obviously crucial for the relevance of the outcome of the study. We used STZ to induce diabetes and insulin pellets to modify the type-1 diabetic state into the more type-2-like diabetes of pregnancy. In agreement with this aim, the dependence on insulin increased with the duration of pregnancy. The genetic non-obese diabetic (NOD) model resembles the STZ model in also being an autoimmune type-1-like model [80], but has not been studied extensively as a diabetes of pregnancy model, possibly because it also produces laterality defects [81,82]. Recently, a type-2-like murine model of diabetic pregnancy was reported in which insulin resistance was induced by feeding mice for 15 weeks a very high-fat (~60 en%) diet [83]. The controls were fed a 10 en% fat diet. However, as we (unpublished observations) and others [84,85] have experienced, a high fat content of the diet (>20 en%), as found in the 5020 (9F) and 5015 mouse diets, appears to be a precondition for the development of cardiovascular and neural tube-closure defects in the offspring, because otherwise similar diets that contain <13.5 en% (e.g. mouse diet 5001) do not produce the malformations. Since the effect of dietary fat is established almost instantaneously [84], diet-induced obesity models of diabetic pregnancy offer no obvious advantages over the established STZ model as modified by Loeken [11]. Another caveat of our study is that we carried out gene expression analysis on only 2 stages of development (ED8.5 and 9.5). These stages, which correspond to very early pregnancy in human (~3 weeks gestation), were considered potentially interesting, because they precede the appearance of malformations. Because we could not select for affected embryos we opted to use a validated mouse model of diabetic pregnancy.

Supporting Information

S1 Appendix. The filled out “ARRIVE” guidelines checklist.

https://doi.org/10.1371/journal.pone.0158035.s001

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S1 Fig. Body weight after STZ treatment and linbit implantation.

Body weight was measured before STZ treatment (“0”), 14 days after the first STZ injection, on the day of linbit implantation (arrow) and on the indicated days after linbit implantation. Round (N = 4) and diamond (N = 12) symbols represent two different series of female mice. The error bar show SEMs.

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S2 Fig. H&E stained sections of control and hyperglycemic ED9.5 mouse embryos.

Panels A and C: control, normoglycemic embryos; panels B and D: experimental, hyperglycemic embryos. Bar: 100 μm.

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S3 Fig. Correlation between total RNA input and number of sequenced genes after SOLiD SAGE sequencing.

Between ~0.3 and 5.2μg total RNA from 29 hyperglycemic and control embryos was used for SOLiD SAGE deep sequencing. The X-axis indicates the amount of RNA used for cDNA synthesis and sequencing, while the Y-axis indicates the saturation in the number of unique expressed genes for each individual embryo.

https://doi.org/10.1371/journal.pone.0158035.s004

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S4 Fig. Genes differentially expressed in hyperglycemic ED8.5 and ED9.5 embryos associated with cardiovascular and/or neural defects.

Panel A: 1024 and 2148 were differentially expressed unique functional genes in embryos from hyperglycemic and control dams on ED8.5 and 9.5, respectively, 876 of which were common to ED8.5 and ED9.5. Panels B-D show Venn diagrams of the number of differentially expressed genes associated with cardiovascular (panel B), neural (panel C), and both cardiovascular and neural malformations in Jackson’s MGD database in ED8.5 (blue), ED9.5 (red), or both ED8.5 and ED9.5 embryos (overlap).

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S5 Fig. Prevalence of genes that were differentially regulated in hyperglycemic ED8.5 and ED9.5 embryos in the MGD data base.

Approximately 45% of the detected differentially expressed sequences represented unique genes at both ED8.5 and ED9.5 (removal of Riken, expressed sequence tags (EST), unassigned and hypothetical genes). Of these, ~21% and ~5% were 5- and 10-fold upregulated, respectively, at ED8.5 and ~14% and ~4%, respectively at ED9.5. Approximately 26% of the differentially regulated genes are associated with cardiovascular, neural, or embryogenesis defects if absent. (MGD data base). Among ≥ 5-fold upregulated genes, this percentage is 23–24% and among ≥ 10-fold upregulated genes 18–20%.

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S1 Table. Criteria to determine the developmental stage of ED8.5 and ED9.5 embryos.

The age of embryos was defined according to the criteria of Kaufman [30].

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S2 Table. PCR primers used.

In all cases, the annealing temperature was 60°C.

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S3 Table. Unique differentially expressed genes in ED8.5 and ED9.5 hyperglycemic and control embryos, and their presence or absence in the MGD database.

All listed genes (1024 at ED8.5 (sheet 1) and 2148 at ED9.5 (sheet 2)) are unique and were >1.5-fold in- or decreased in expression (Padj < 0.05) in hyperglycemic embryos. Columns A to H represent “Gene Name”, “Ensembl Gene”, “Unigene”, “Fold Change”, “Log2 Fold Change”, “P adjusted value”, “Chromosome” and “Gene Description”, respectively. The gray fields indicate that the indicated gene was ≥ 5-fold up- or downregulated and present in the subfield cardiovascular, neural, and embryogenesis defects of the Jackson Laboratory Mouse Genome Database (MGD). Columns L to W represent the normalized number of reads for the hyperglycemic and control embryos at ED8.5 and columns L to AA at ED9.5.

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S4 Table. Expression levels of genes shown in Fig 5.

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Acknowledgments

We are grateful to Dr Mary R. Loeken (Joslin Diabetes Center, Research Division, Harvard University, Boston, MA) for advice on the implementation of the diabetic mouse model, Dr Jan M. Ruijter for statistical advice and discussions, and Eduardo Hideo Gilglioni (Tytgat Institute for Liver and Intestinal Research) for sharing oxygen consumption and extracellular acidification rates in hepatocytes.

Author Contributions

Conceived and designed the experiments: JZ TBMH WHL. Performed the experiments: JZ TBMH. Analyzed the data: JZ TBMH AMW AJ MS. Contributed reagents/materials/analysis tools: EJB VCJDB FB AHCVK. Wrote the paper: JZ TBMH WHL.

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