Mice models are an important way to understand the relation between the fetus with cleft palate and changes of maternal biofluid. This paper aims to develop a metabonomics approach to analyze dexamethasone-induced cleft palate in pregnant C57BL/6J mice and to study the relationship between the change of endogenous small molecular metabolites in maternal plasma and the incidence of cleft palate. To do so, pregnant mice were randomly divided into two groups. The one group was injected with dexamethasone. On E17.5th day, the incident rates of cleft palate from embryos in two groups were calculated. The H1-NMR spectra from the metabolites in plasma in two groups was collected at same time. Then the data were analyzed using metabonomics methods (PCA and SIMCA). The results showed that the data from the two groups displayed distinctive characters, and the incidence of cleft palate were significantly different (P<.005). To conclude, this study demonstrates that the metabonomics approach is a powerful and effective method in detecting the abnormal metabolites from mother in the earlier period of embryos, and supports the idea that a change from dexamethasone induced in maternal metabolites plays an important role in the incidence of cleft palate.
1. Introduction
Congenital cleft lip and palate (CLP) is the most common birth defect in humans. The etiology is complicated, and it involves genetic and environmental factors [1, 2]. Maternal condition during pregnancy also appears to play an important role [3]. Smoking [4–6], over intake of vitamin A [7, 8], and deficiency in folic acid and Bs may increase risk for oral clefts [9–12]. In addition, drug-induced (corticosteroid) teratogenesis has also received some attention [13–16]. Most studies above are based on epidemiological investigation. As a useful model, experiments of mouse development are used to assess the mechanism of palate defects in fetuses resulting from exposure to the risk factors. Current strategies to study orofacial defects focus on the related genotype and transcription factors [17, 18]. However, the capability of maternal detoxification during orofacial development is important for normal palate formation. As a result, a fetus lacking genes associated with cleft palates still has high risk of defect if maternal detoxification is insufficient. [2, 19]
Metabonomics, based on the NMR spectroscopic and multivariate statistics, can be useful for the description and recognition of the dynamic multivariate metabolic response of an organism to a pathological event or genetic modification. The 1H-NMR spectra of the biofluids from an organism contain a significant amount of useful metabolic information. Application of automated data reduction algorithms and chemometric analysis, which is called pattern recognition analysis (PR), can be competent for the description and recognition of the dynamic multivariate metabolism. It is included two major approaches, one is termed “unsupervised”, which could be used to not only reduce the complex and volume data to a suitable level but also screen for the outlier and examine condition of the clusters, including Principal Component Analysis (PCA), Nonlinear Mapping (NLM) and Hierarchical Cluster Analysis (HCA). The other is termed “supervised” that means, make a mathematical model by a training set of known class from the samples and then draw the estimated or predictive model by independent validation set. There are many methods such as Soft Independent Modeling of Class Analogy (SIMCA), Partial Least Squares (PLS), Linear discriminant analysis (LDA), K-nearest neighbor analysis (KNN), and Bayesian methods. These approaches have been successfully applied to study diseases and toxic processes [20–27]. Principal component analysis (PCA) as a bilinear decomposition method is one of the most easy and efficient approaches to analyze the NMR data, A PCA model can trustily display a summary of all samples in the data table [27]. Combination with using a prediction model, such as SIMCA, can be constructed to analyze the unknown samples [28–30].
Development of the mammalian palate involves a number of critical steps: growth, elevation, contact, and fusion (the medial edge epithelium disappearance). Any problem arising from these steps can lead to the incidence of cleft palate. DEX, one of the glucocorticoids (GC), can penetrate the blood-placental barrier and bind to GC receptor (GR) in the cytoplasm, and can depress the ability of palatal mesenchymal proliferation. Since the palate is smaller, development of bilateral palates is interrupted, which results in the cleft [31–34]. We hypothesized that the metabonomic method could provide the framework for the studies on the consequences of maternal environmental changes during pregnancy and for illustrating the relationship between the changes of maternal environment and development of palates. To test this hypothesis, we studied the plasma samples from pregnant C57BL/6J mice, which were induced with dexamethasone (DEX) to trigger cleft palate formation in the fetuses. The analyses demonstrated the relationship between the change in endogenous small molecular metabolites of maternal plasma and the incidence of cleft palate (CP) in fetuses.
2. Materials and Methods2.1. Animal Handling and Dosing
All animal experimentation was approved by the Animal Research Committee of the West China College of Stomatology (Sichuan University). C57BL/6J (C57) mice, about 8 weeks of age, were obtained from the Laboratory Animal Center of Sichuan University. All mice were reared in plastic cages (28cm×16cm×12cm), under a 12/12-hour light/dark cycle. The room was maintained at a controlled ambient temperature of 20–27°C with 40%–70% relative humidity. A commercial diet (Laboratory Animal Center of Sichuan University, China) and tap water were fed ad libitum. Mice were allowed to acclimatize for 48 hours prior to mating. Two virgin females and one male were placed overnight in a cage and checked on following morning for the copulatory plug of female mice. Females with copulation plugs were weighed immediately and the date was designated to Embryonic day 0(E0).
Pregnant mice (42) were randomly divided into two groups (the experimental group and the control group,each group 21 mice). From the 10th day to the 12th day of pregnancy (From E10 to E12), the mice in the experimental group were intraperitoneally injected daily with Dexamethasone (DEX dexamethasone sodium phosphate injection, Tianjing China) at 6 mg/kg,and while the others in the control group with isotonic sodium chloride (0.9% NaCl). The dose levels were based on the literature report [35].
2.2. Sample Collection
On the day of E17.5, all the pregnant mice were sacrificed and weighed. The peripheral blood was placed in a lithium heparin tube (Vacuette Austria) immediately. Within 2 hours of the collection, the erythrocytes were separated by centrifugation (3000×g at 4°C or 10 min) to pick up the biofluid top of the plasma for analysis. All the plasma samples were stored at -80°C before the 1H-NMR analysis. At the same time, a stereomicroscope was used to determine the number of live fetuses and gross malformations.
2.3. Statistical Analysis of the Incidence of Cleft Palate
After removal of the mandibles, embryonic palates were calculated using stereomicroscope (10×) by morphologic in two groups. Target palates were processed into paraffin wax. Histological sections of embryonic palates were cut and stained with haematoxylin and eosin (HE). The results were photographed by a Leica photographic system (Germany). The numbers of CP in two groups were analyzed to detect the different incidence rates by using chi-square test and variance-based statistical algorithm (SPSS 10.0).
2.4. Preparation of Plasma Samples for 1H-NMR Spectroscopy
The 1H-NMR spectra were obtained immediately after each sample was thawed at 300 K and then kept at the same temperature in a Bruker Avance II 600 spectrometer (Bruker Biospin, Germany), which was operating at 600.13 MHz with a 5-mm PATXI probe. In order to obtain a deuterium lock signal for the NMR spectrometry, 200 μl aliquots of all the plasma were diluted up to 500 μl with 300 μl of Deuterium oxide (D2O).
2.5. Acquisition of 1H-NMR Spectra of Plasma
The spectrum was obtained by using two different pulse sequences: one is selective presaturation pulse sequence (Bruker Biospin, Germany) for water suppression (located in δ 4.8 ppm) and other is CPMGPR1D pulse sequence (Bruker Biospin, Germany). The later one, which was used to attenuate the broad protein signal in the plasma, is a modification of the Carr-Purcell-Meiboom-Gill pulse sequence (CPMG-pulse, Bruker Biospin Germany) to suppress the residual water signal. For each sample, 1D 1H-NMR spectrum was collected with 64 K data points, 64 scans and 15 ppm spectral width. Other acquisition parameters were 5 s relaxation delay, 8 dummy scans, 400 μs fixed echo time to allow the elimination of J-mod, and 400 CPMG loops for T2 filter. The phase and the baseline of all acquired NMR spectra were manually calibrated, and the chemical shifts corrected by the reference of the lactate doublet at δ1.32 [36] with TopSpin 1.3 (Bruker Biospin, Germany).
2.6. Reduction of the NMR Spectral Data
All signals of the 42 samples’ were located in the range of δ 0–7 ppm in spectral region and have no visible resonance peak after δ 7 ppm. Using MestReC (version 4.8.1.1, Spain), each 1H-NMR spectrum was divided with δ 0.04 ppm width into 162 contiguous segments and integrated from the rang of δ 0–7 ppm [37, 38]. The region of the spectrum (δ 5.0–4.5 ppm) was removed to exclude the influence of the water signal. The result was set up to a kind of 2D matrix (n×d), “n” representing the 42 samples, “d” meaning 162 contiguous segments. The matrix data were normalized to the unit area with the appropriate weighting coefficients in Excel (Microsoft USA) and then exported into the SIMCA-P software package (version11.0, Umetrics AB, Umeå, Sweden). The average value of each variable was calculated and subtracted from the data.
2.7. Statistical Analysis of the Data from NMR Spectra
After the average value being calculated from each variable and subtracted from the data, PCA was applied to the mean-centered data to detect the differences among the samples. SIMCA was performed to validate the results. Firstly, separate PC models were built for the training sets of 10 samples from DEX group with CP fetuses and 10 samples including only normal fetus of control group and were defined two distances against boundaries (cross-validation) by the 95% confidence interval. As a typically visualizing method, the Cooman’s plot was often used to display the result [39]. SIMCA formulated a PC model for each distinct class and estimated its performance. Secondly, the procedure was repeated for all samples (the test sets) in turn, to predict and assess whether samples were separated into two classes. Finally, the result of the Cooman’s plot illustrated the visible separation of two groups. Each step was repeated five times in order to keep the validation set.
3. Results3.1. The Statistics of the Incidence of Cleft Palate in Two Groups
Forty-two C57BL/6J pregnant mice were examined, and 229 fetuses were collected, including 123 fetuses from DEX treatment group and 106 fetuses from the control group (Table 1). Each pregnant mouse had multiple fetuses. There was at least one CP fetus in each pregnant mouse in DEX treatment group (named DEX group), while there were 3 CP fetuses in two pregnant mice of the control group (named the control group with CP). The incidence of CP in the DEX treatment group was 21.95%, significantly different from the control group (P<.005). The character of morphology and histology were recorded (Figure 1). “a” and “c” show fusion of palate shelves, while “b” and “d” show a failure of the palate shelves to fuse.
Comparison of the incidence of cleft palate in the embryos between two groups.
Non-Fusion
Fusion
Total
Incidence of non-fusion (%)
Control group
3
103
106
2.83
DEX group
27
96
123
21.95*
Total
30
199
229
13.10
Significant* difference with respect to control (χ2=18.285,P<.005).
Photos of fusion or lack of fusion by embryonic palatal shelves. The fusion situation of embryonic palatal shelves was observed and photographed. (a) Fused embryonic palatal shelf. (b) Nonfused embryonic palatal shelf. (c) Fused embryonic palatal shelf in histological section. (d) Nonfused embryonic palatal shelf in histological section.
3.2. 1H-NMR Spectra from Two Groups
The 1H-NMR spectrum of the plasma from pregnant mice revealed great complexity and significant information about the biofluid (Figure 2). The chemical shift of δ 4.8 was the water signal. The regions of the significant metabolite signals usually ranged δ 0–4.5 ppm, including alkene (δ 4–5.5 ppm), alkyne (δ 1.8–3.5 ppm), and the aliphatic series (δ 0–2.8 ppm). Articles of the locations of different chemical groups and some low-molecular-weight metabolites had already been published [36, 40]. To detect the difference between the two groups, special software was used in the chemometric analysis.
600 MHz 1 H-NMR spectra of plasma samples from the pregnant mice in two groups: “a” showed the spectrum from one sample in the control group; “b” showed the spectrum from one sample in the DEX group.
3.3. PCA of the Plasma in the DEX Group and the Control Group
The matrix data from the 1H-NMR spectra were exported into the SIMCA-P software and processed by PCA. The new principal component (PC) variables were created (6 new contributories of the PCs), which accounted for 84.8% of the original data and each PC was orthogonal with all the other PCs. The result of PCA could be shown (Figure 3) as the clustering of the individual dataset defined by the 95% Hotelling’s T2 Limit. Except for two control samples (*: the blue star), all the 21 DEX samples (▴: the black triangles) and 19 control samples with fusion fetuses (□: the open squares), obviously, were separated well along the first principal component. It indicated that the major difference between the two groups occurred in the first two principal components. The detailed different biochemical changes were informed by the loadings (Table 2). In order to detect the outliers, the two outliers as one group to be detected with Dex group and control group respectively. PCAs were repeated twice again using different groups (Figure 4). The result indicated that the two outliers with CP fetuses have some extent different from the control group, while mixed in the Dex-injected group because of CP fetuses.
the main metabolites changes that were partially responsible for discriminating Dex group from control using PCA.
1H bucket region (δ)
metabolites
Changes in Dex group
1.32, 4.12
Lactate
↑*
1.36
unknown
↑
1.48
Alanine CH3
↑
1.72
Arginine(γ-H)
↓
1.92
Arginine (β-H)
↓
2.02
Acetate
↑
2.04
Lipid CH2CH2CH=CH
↑
2.12
Glutamine
↑
2.28
Valine (β-H)
↓
2.36
Glutamate
↑
2.4801
unknown
↑
2.5201
Lipid –C=C–CH2–C=C
↓
2.8
Aspartic acid (β-H)
↓
3.24
Choline N (CH3)3+
↑
3.64
Valine (α-H)
↓
3.92
Creatine
↑
4.04
myo-inositol
↓
↑*, relative increase in signal by loading plot.
The plot of PCA analysis from two groups. “▴” showed the data from pregnant mice with CP fetuses in DEX group; “□” showed the data from pregnant mice with fusion fetuses in control group. “*” showed the pregnant mice including CP fetuses in the control group.
The plots of PCA analysis for two control pregnant mice including CP fetuses in different groups “a” showed the PCA analysis between two outliers from the control group and the data of pregnant mice with CP fetuses in DEX group; “b” showed the PCA analysis between two outliers from the control group and the data of pregnant mice with no-CP fetuses in control group.
3.4. SIMCA of the Plasma in the DEX Group and the Control Group
The result of SIMCA was shown in the Cooman’s plot (Figure 5). All the samples had been tested with an independent model made of train set. The condition of samples can be classified in a pair of distances against boundaries (red lines) for non-fusion data in DEX group and fusion data in control group. The plot contained four regions separated by 95% confidence limits in a 2D graph in which samples below the horizontal line belonged to the control group with fusion fetuses (95%), while samples in the left region of the vertical line belonged to DEX group with CP fetuses (95%). The data from control group with CP fetuses (the outliers) neither belongs to DEX group nor belongs to control group. It demonstrated that plasma classes from pregnant mice with CP fetuses and normal control did not share the same space. Therefore, this model should be able to predict whether maternal environment has been affected by DEX or not.
The Cooman’s plot of two groups in test set from SIMCA. “▴” showed the DEX group with CP fetuses; “□” showed the control group with fusion fetuses; “*” showed two outlier samples (pregnant mice with CP fetuses in control group); the red lines indicate the D-Crit (0.05) level; two groups were located in two different spaces; the outliers not belong to either group.
4. Discussion
In the normal mouse embryo, palate shelves grow and elevate into a horizontal position by embryonic day 14 (E14). By the day of E17, the process of fusion has completely finished. We chose to collect samples on E17.5 for the following reasons. It was convenient to use morphology for embryo analysis, and it was easy to display the change of maternal metabolism without the influence of DEX [41]. Furthermore, another study also proved that the spectra of plasma from Dex-injected and control male mice showed no significant difference during different time frames (2 hours, 1 day, 2 days, 3 days, and 7 days). The PCAs also show that all data from different time frames were a mixture together, which accounted for 89.9% from the original data (supplement).
Different murine strains also have different susceptibilities to the DEX-induced cleft palate. The incidence in our model was in accord with previous work [42]. Some studies indicate [43–45] that the incidence of cleft palate may be closely related to high maternal concentration of plasma homocysteine or lower activity of the glucocorticoids prereceptor metabolizing enzyme11β-hydroxysteroid dehydrogenase type 2 (11β2HSD2) in placental trophoblastic cells. However, the exact mechanisms by which interaction between maternal environment and DEX causes teratogenic effects are poorly understood. NMR spectroscopy-based metabonomic approach offers a unique opportunity to focus on the relationship between genotype and phenotype and is especially suited to uncover changes in drug-induced metabolites [46, 47]. In this study, each mother at least has one CP fetus in DEX-injected group. Some changes of maternal metabolites informed us about the abnormality of the embryo. Therefore, the result from two groups displayed the different metabolites between CP fetus and fusion one. From the spectra of 1H-NMR (Figure 2), we can see clearly some differences between the samples of the two groups within the range of chemical shift from δ 1.8 to δ 3.5 ppm and the range of glucose and amino acid CH. The PCA plots showed good separation of the two groups except for two control samples (Figure 3), which matched the results from morphologic analysis identifying three cleft palate fetuses from two different individual mice in the control group. In order to analyze the outlier from the control group, the two outliers as a group were analyzed again. The result also show these two samples were closely blended in the DEX group (Figure 4(a)), while far away from the controls’ (Figure 4(b)). Some biochemical changes such as decrease of Arginine (1.72, 1.92 ppm), increase of Alanine (1.48 ppm), N-acetyl glycoprotein (2.12 ppm), Choline (3.24 ppm), and Creatine (3.92 ppm) may response to the change of methyl group metabolism in maternal environment. The key donor of methylation is S-adenosyl methionine (SAM) which comes from methionine. Arginine and Creatine may increase ATP to supply the circle from methionine to homocysteine [48]. Normally, the incidence of cleft palate in C57BL/6J natural mice is zero. The reason may be that we injected isotonic sodium chloride (0.9% NaCl) in control samples in order to keep the same stimulating circumstance as in the DEX group. After SIMCA analysis, the result of the Cooman’s plot revealed a good fit model to detect the NMR data and separate the CP group from the controls by using a test set of F-statistic. Both plots clearly showed a relationship between the fetus’ cleft palate and the plasma metabolic profile of the mother. In conclusion, this study provides evidence that metabonomic method is sufficiently sensitive to detect small differences in the composition of maternal biofluids and may be helpful for identifying biomarkers of teratogenesis.
Conflict of Interest Statement
The authors declare no conflict of interests.
AbbreviationsPRA:
Pattern recognition analysis
DEX:
Dexamethasone
HE:
Haematoxylin and eosin
CPMG:
Carr-Purcell-Meiboom-Gill pulse sequence
PCA:
The principal component analysis
SIMCA:
Soft independent modeling of class analogy
GC:
Glucocorticoids
GR:
GC receptor
CP:
Cleft palate.
Acknowledgments
This study was supported by Grants from the Key Research Project of the Ministry of Education in China (no.307022), the National Natural Science Foundation of China (no. 30530730) and the Youth Teacher Science Foundation of Sichuan University (no. 2009SCU11162). The authors are grateful to Dr. Shan Lu, PhD and Chapin Rodriguez, PhD for their useful comments.
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