Abstract
Background
Pre-eclampsia (PE) is a common condition in pregnancy; however, methods for early diagnosis and effective treatment options are lacking. Ferroptosis is a newly identified iron-dependent cell death pathway. The aim of this study was to investigate the role of ferroptosis-related genes in PE, the underlying mechanism, and their potential diagnostic value using a bioinformatics approach.
Methods
We downloaded the GSE48424 and GSE98224 datasets from the Gene Expression Omnibus database. Differentially expressed genes (DEGs) between PE and healthy pregnancy samples were identified in the GSE48424 dataset and subjected to weighted gene co-expression network analysis; the most relevant modules were intersected with known ferroptosis-related genes to distinctly identify the role of ferroptosis in PE. We further searched transcription factors and microRNAs that are predicted to regulate these ferroptosis-related genes, and patients in the GSE48424 dataset were divided into two groups according to high or low expression of the key ferroptosis-related genes associated with PE. To obtain robust key ferroptosis-related genes in PE, we validated their expression levels in the external dataset GSE98224. Finally, the reverse transcription-quantitative polymerase chain reaction (RT-qPCR) assay was utilized to access the expression of these genes in the PE and normal blood samples.
Results
Six ferroptosis-related genes involved in PE were obtained by overlapping 3661 genes most associated with PE, 565 DEGs between PE and normal samples, and 259 known ferroptosis-related genes. Among these genes, patients with PE displaying lower expression levels of NOS2 and higher expression levels of PTGS2 had a higher ferroptosis potential index. The expression pattern of NOS2 was consistent in the GSE48424 and GSE98224 datasets. RT-qPCR data confirmed that NOS2 expression was more significantly elevated in patients with PE than in those with a normal pregnancy.
Conclusions
Our study explored the diagnostic value of ferroptosis-related genes in PE, and identified NOS2 as the key gene linking ferroptosis and PE, suggesting a new candidate biomarker for early PE diagnosis.
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Background
Pre-eclampsia (PE), characterized by organ damage and hypertension after 20 gestational weeks, has a prevalence of 2–8%. PE is associated with short-term complications such as cardiac, hepatic, pulmonary, renal, and neurological dysfunction, and high maternal and neonatal mortality. Long-term complications include a higher risk of cardiovascular events [1, 2]. The abnormal migration and invasion of the extravillous trophoblast toward the uterine spiral arteries, which is the main cause of PE, lead to neovascularization and uteroplacental vascular resistance [3, 4]. However, the exact pathophysiology of PE is unknown, and early diagnosis and treatment are lacking. Early diagnosis facilitates rapid clinical intervention and minimizes maternal and fetal damage. Therefore, the pathogenesis of PE requires further analysis, and it is important to find reliable diagnostic markers.
Programmed cell death typically occurs in the biological development process. Although previous studies in this regard have mainly focused on autophagy and apoptosis, the role of ferroptosis has become a research hotspot in recent years. As another form of programmed cell death, ferroptosis is quite distinct from the classical programmed cell death forms (e.g., apoptosis) [5, 6], with iron-dependent lipid-peroxidative damage as the main mechanism. Ferroptosis has been shown to play a role in several diseases such as asthma, brain damage, cancer, ischemic heart disease, and acute kidney injury [7,8,9,10,11]. At present, there is mounting evidence suggesting that ferroptosis has been related to PE [12]. The pathophysiological processes of PE, including placental hypoxia-reperfusion, abnormal placental perfusion, a rich iron content in the trophoblast, and reduced glutathione peroxidation capacity, are all linked to conditions associated with ferroptosis [13, 14]. Some studies have recorded the lipid peroxidation of trophoblasts in placental injury [15]. The concentration of plasma iron in PE pregnancy is higher than that in normal pregnancy [16]. There are also several articles exploring the relationship between ferroptosis and PE using bioinformatics methods [17, 18]. We were wondering if we could find biomarkers that were diagnostic for PE using different bioinformatics methods.
Investigation of the relationship between ferroptosis-related genes and PE can enrich our understanding of PE etiology and guide the early detection of PE. Thus, the aim of this study was to identify diagnostic ferroptosis-related biomarkers for the early diagnosis of PE using bioinformatics analysis and validation assays with clinical samples .
Methods
Data source
We recruited 16 pairs of patients with PE matched with women undergoing a normal pregnancy from the Department of Obstetrics of Guangdong Women and Children Hospital (China). The Ethics Committee of Guangdong Women and Children’s Hospital approved the study (No. 202,101,012), and all participants provided informed consent. Inclusion and exclusion criteria are as follows: PE was defined as new onset of systolic blood pressure elevation of at least 140 mmHg, or diastolic blood pressure of at least 90 mmHg on at least two occasions that were at least 4 h apart. This would need to be accompanied by one or more of the following features: proteinuria (≥ 300 mg/24 h), maternal organ dysfunction (including renal, hepatic and neurological), hematological involvement, and uteroplacental dysfunction. Pregnant women with cardiovascular diseases, liver or kidney diseases, endocrine diseases, or fetuses with malformations or chromosomal abnormalities were excluded. The clinical features of the patients are shown in Table 1.
Transcriptome data from patients with PE and normal pregnancies were downloaded from the GSE48424 dataset, including 18 control and 18 PE blood samples, and the GSE98224 dataset, including 18 control and 30 PE placenta tissue samples, of the Gene Expression Omnibus (GEO) (http://www.ncbi.nlm.nih.gov/geo) database to screen for ferroptosis-related genes involved in PE. Ferroptosis scores of the control and PE groups in the GSE48424 dataset were calculated by single-sample gene set enrichment analysis (ssGSEA) using a ferroptosis-related gene set from the FerrDb database (www.zhounan.org/ferrdb) [19].
Differentially expressed gene (DEG) identification and functional analysis
We used the “limma” package in R (version 4.0.0) to identify the DEGs between PE and control samples with p-value < 0.05 and |fold change (FC)| >1.5. DEG function, interactions among enriched biological processes, and pathways were analyzed using Metascape [20]. We constructed a sample clustering tree map from the GSE48424 dataset.
Weighted gene co-expression network analysis (WGCNA) and identification of the most relevant module associated with PE
To eliminate outliers and ensure the best soft threshold depending on gene expression profiles and patient grouping (control and PE groups), we performed WGCNA using R software package. We used Pearson correlation coefficients to determine the most relevant module associated with PE.
Identification of potential diagnostic ferroptosis-related biomarkers in PE
DEGs, ferroptosis-related genes downloaded from the FerrDb database, and genes in the most relevant module identified by WGCNA were intersected to identify candidate ferroptosis-related genes involved in PE. Subsequently, the diagnostic value of candidate ferroptosis-related genes involved in PE was assessed by construction of receiver operating characteristic (ROC) curves. Candidate ferroptosis-related genes with area under the ROC curve (AUC) values greater than 0.7 were identified as potential diagnostic ferroptosis-related biomarkers in PE.
The Harmonizome database was used to search for transcription factors (TFs) that regulate the expression of the candidate diagnostic ferroptosis-related biomarkers in PE. The regulatory network of microRNAs (miRNAs) and TF diagnostic biomarkers was visualized using Cytoscape. Potential diagnostic ferroptosis-related biomarkers in PE were captured into the miRWalk database to screen for miRNAs targeting the diagnostic biomarkers (score > 0.9).
Patients with PE in the GSE48424 dataset were separated into high- and low-expression groups according to the median expression value of each diagnostic biomarker. The ferroptosis potential index (FPI) was calculated based on the expression levels of genes in the core ferroptosis machinery by ssGSEA, including the positive regulators NFE2L2, LPCAT3, GPX4, NCOA4, ACSL4, SLC3A2, ALOX15, SLC7A11, NOX3, NOX1, NOX5, and NOX4, and the negative regulators COQ10B, HMGCR, FDFT1, and COQ10A, as described in a previous study [21]. Thereafter, candidate key ferroptosis-related genes were identified according to a significant difference between the low- and high-expression groups. Gene expression was validated in the external dataset GSE98224 to obtain robust key ferroptosis-related genes in PE. The biological functions of key ferroptosis-related genes in PE were analyzed by GSEA.
Western blot analysis
Placental tissue samples (1 × 1 × 1 cm3) were randomly collected from the basal plate (2 cm from the periphery, avoiding placental infarcts) immediately after delivery, and washed in cold normal saline to remove any contaminating blood. The tissue was immediately frozen at − 80 °C for immunoblotting experiments.
40 mg of tissue from different groups were lysed with RIPA buffer. Protein concentrations were quantified by BCA kit. Total protein (25 µg) was separated by SDS-PAGE, and then transferred to PVDF membranes which were clipped to the appropriate size covering all the sample lanes prior to transfer. The PVDF membranes were blocked with 5% skim milk and incubated with anti-NOS2 antibody (1:1000 dilution; Proteintech Group; No: 80517-1-RR) and anti-β-actin antibody (1:5000 dilution; Abcam; No: ab8226) overnight at 4 °C. The membranes were eluted three times with TBST for 10 min each, followed by incubation with 1:5000 HRP-conjugated secondary antibodies at room temperature for 1 h. The immunoreactive bands were visualized with chemiluminescence detection reagents by Bio-RAD camera system and analyzed by ImageJ software for relative expression of proteins.
Validation with reverse transcription-quantitative polymerase chain reaction (RT-qPCR)
All patient samples were collected at the Department of Obstetrics, Guangdong Women and Children Hospital (Guangzhou, China). Venipunctures were performed, and 3 milliliters (ml) of whole blood was collected into 5-ml EDTA-coated Vacutainer tubes before any medical interventions. All samples were stored in a freezer at − 80 °C for future study.
TRIzol reagent (Tiangen, Beijing, China) was used to extract the total RNA from patient samples. The Revert Aid RT-PCR system was then used to perform reverse transcription to synthesize cDNA, and qPCR was performed on the ABI 7500 Real-Time PCR System (Roche, Penzberg, Germany) by mixing cDNA, primers, and the Rox Reference Dye. The conditions for qPCR were as follows: 40 cycles of denaturation (95 °C, 10 s), annealing (55 °C, 20 s), and extension (72 °C, 35 s). The primer sequences were shown in Table 2. The mRNA expression levels were calculated using the ΔΔCT method with GAPDH as a reference.
Statistical analysis
All data were analyzed using R software version 4.0.0. Boxplots and volcano plots were plotted by ggplot2 package in R (version: 3.3.2). The significance of differences between PE and normal groups was calculated by ggsignif package (version 0.6.0). T-test was used to compare ferroptosis scores between PE and normal samples. A p-value < 0.05 was considered to indicate statistical significance.
Results
DEGs in PE are associated with immune and lipid metabolism
The workflow of the current study is displayed in Fig. 1. We identified 565 DEGs, including 378 downregulated and 187 upregulated genes in PE compared with control samples (Fig. 2A). Metascape confirmed that these DEGs were largely enriched in immune- and lipid metabolism-related biological processes, including the metabolism of lipids, regulation of the mitogen-activated protein kinase cascade, T cell activation, inflammatory response, cytokine–cytokine receptor interaction, tumor necrosis factor signaling pathway, and regulation of lipid metabolic process (Fig. 2B). Metascape further revealed that these biological processes and pathways interact (Fig. 2C), indicating that the pathogenesis of PE is complex and regulated by cross-talk among multiple biological processes and pathways.
Most relevant module associated with PE identified by WGCNA
No outlier sample was detected in the GSE48424 dataset (Fig. 3A). The trait heatmap and sample dendrogram are shown in Fig. 3B. The optimal soft threshold power was identified as 6, for which the R2 was 0.85 (Fig. 3C). After merging similar modules, we identified 15 modules from the co-expression network (Fig. 3D). The ME (blue) module, comprising 3661 genes, was the most relevant module associated with PE (correlation coefficient = 0.41, p = 0.01) and was thus selected for further analysis.
Identification of five diagnostic ferroptosis-related biomarkers in PE
We compared the ferroptosis scores between PE and control samples by ssGSEA. The PE group had significantly (p < 0.05) lower ferroptosis scores than the control group (Fig. 4A), indicating that ferroptosis is involved in the etiology of PE. Six candidate ferroptosis-related genes involved in PE were identified by overlapping the 565 DEGs, 3661 genes identified in the most relevant WGCNA module, and 259 known ferroptosis-related genes (Fig. 4B). ROC curve analysis was applied to evaluate the diagnostic value of the six candidate ferroptosis-related genes. The AUC values for PTGS2, GCH1, HIF1A, BACH1, NOS2, and ATF3 were 0.824, 0.794, 0.774, 0.758, 0.721, and 0.695, respectively (Fig. 4C). Therefore, PTGS2, GCH1, HIF1A, BACH1, and NOS2 were identified as candidate diagnostic ferroptosis-related biomarkers in PE.
Regulatory network of diagnostic ferroptosis-related biomarkers in PE
The ChEA Transcription Factor Targets function in Harmonizome was used to screen TFs regulating the expression of PTGS2, GCH1, HIF1A, BACH1, and NOS2. A regulatory network of PTGS2, GCH1, HIF1A, BACH1, NOS2, and 85 TFs was constructed and visualized using Cytoscape (Fig. 5A). PTGS2, GCH1, HIF1A, BACH1, and NOS2 expression was found to be regulated by both specific and common TFs. We also detected the miRNAs targeting these five biomarkers using the miRWalk database and constructed the miRNA–mRNA network using Cytoscape. We found 31 miRNA–GCH1 pairs, 37 miRNA–BACH1 pairs, a has-miR-2467-5p–NOS2 pair, 17 miRNA–HIF1A pairs, and 16 miRNA–PTGS2 pairs (Fig. 5B).
Identification of NOS2 as the key ferroptosis-related gene in PE
To investigate the importance of these six candidate biomarkers in mediating the ferroptosis-related etiology of PE, we divided pregnant women with PE into low- and high-expression groups according to the median expression level of each biomarker. The low-NOS2 group had a significantly (p < 0.05) higher FPI than that of the high-NOS2 group (Fig. 6A),and the high-PTGS2 group had a significantly (p < 0.05) higher FPI than the low-PTSG2 group(Fig. 6B). No significant difference was detected between low- and high-expression groups with respect to the levels of GCH1, HIF1A, and BACH1 (Fig. 6C–E), indicating that NOS2 and PTGS2 have greater contributions to the ferroptosis-related etiology of PE. Furthermore, the abundance of NOS2 was higher in the PE group, whereas the abundance of PTGS2 was higher in the control group in the GSE48424 dataset (Fig. 7A). The expression pattern of NOS2 was validated in the GSE98224 dataset (Fig. 7B). Thus, NOS2 was considered to be a key ferroptosis-related gene in PE. ssGSEA showed that sympathetic nervous system development was significantly enriched in the high-NOS2 expression group (p < 0.01, Fig. 7C), suggesting the potential mechanism by which NOS2 is involved in PE.
We evaluated the protein level of NOS2 in placental tissue using Western blot, and the results showed NOS2 expression was significantly elevated in the PE group compared with the normal pregnancy group (Fig. 8A). Validation with RT-qPCR confirmed that the NOS2 mRNA expression level was significantly elevated in patients with PE compared with that of pregnant women undergoing a normal pregnancy (Fig. 8B).
Discussion
PE has dire consequences for both maternal and neonatal health. However, early diagnosis and radical treatment for PE are lacking as its etiology is not well-understood. As a novel regulated form of cell death, ferroptosis has recently been shown to play a role in the development of multiple diseases [22], making it a promising biomarker to aid in early diagnosis. This study investigated the diagnostic value of ferroptosis-related genes in PE.
We identified 565 DEGs that mainly participate in the lipid metabolism and immune processes. Previous studies reported that a large amount of energy required for placental and fetal development is provided by free fatty acids (FFAs). Lorentzen et al. [23] reported that the serum levels of FFAs such as linoleic acid, palmitic acid, and oleic acid are elevated in patients with PE, and lower levels of long-chain polyunsaturated fatty acids in either the placenta or maternal circulation have also been related to PE pregnancies [24,25,26]. Moreover, altered fatty acid oxidation may contribute to the pathophysiology of PE [27]. Accumulating evidence indicates that improper activation of the immune system may lead to the development of PE [28]. These findings suggested that lipid metabolism and immunity are closely related to PE.
Indeed, we found that the ferroptosis scores of patients with PE were significantly lower than those of women undergoing a normal pregnancy, indicating that iron-mediated cell death is involved in PE development. We subsequently found six ferroptosis-related genes associated with PE by intersecting the genes obtained by WGCNA, DEGs analysis, and reported ferroptosis-related genes. Through the ROC curve, we found that five genes—BACH1, GCH1, HIF1A, NOS2, and PTGS2—can effectively distinguish between healthy and PE samples, which could be potential PE diagnostic biomarkers.
Hui et al. [29] reported that miR-133a-3p could relieve oxidative stress-induced apoptosis by targeting BACH1 via regulating the BACH1/NRF2/HO-1 signaling pathway in trophoblast cells. In mammals, GCH1 is the rate-limiting enzyme in biosynthetic processes, which is involved in the synthesis of tetrahydrobiopterin and the pteridine portion of tetrahydrofolate, playing a crucial role in maintaining inflammatory, neurovascular, and cardiovascular homeostasis [30, 31]. However, no studies have identified a role of GCH1 in PE to date.
The expression of HIF1A, which is a negative regulator of RSL3- and erastin-induced ferroptosis in Calu-1 and HT1080 cells [32], was found to be upregulated in the placenta tissues of patients with PE [33]. Takayuki et al. [34] verified that knockdown of HIF1A mRNA could alleviate the syndromes of PE, such as hypertension, organ damage, elevated circulating sFlt-1, and proteinuria, in PE mouse models.
Upregulated NOS2 expression could produce elevated levels of nitric oxide (NO) over extended periods of time. Li et al. [35] found that an increase of the NOS2 level in lysosomes may cause the continuous accumulation of NO, which will induce autophagy and result in raising the lysosomal membrane permeabilization to its threshold along with lysosomal lipid peroxidation, finally leading to ferroptosis. NO is required for uterine spiral artery remodeling and trophoblast migration in early pregnancy. Patients with PE exhibit lower plasma levels of NO, indicating that the reduced bioavailability of NO is involved in PE development [36, 37].
PTGS2 is an inducible enzyme brought about by hypoxia and oxidative stress [38, 39]. Although PTGS2 does not regulate ferroptosis, it has been reported that increased PTGS2 levels could be a suitable marker for ferroptosis [40]. The increased expression of PTGS2 indicates an inflammatory response in PE [41, 42].
We used the FPI to identify that NOS2 and PTGS2 contribute more substantially to the ferroptosis-related etiology of PE among the six candidate biomarkers. The expression pattern of NOS2 was consistent in the GSE48424 dataset, and the expression level of NOS2 in patients with PE was significantly higher than that in women undergoing a normal pregnancy. Collectively, these results suggest that NOS2 is a key ferroptosis-related gene involved in PE. To explain the relevant mechanisms by which NOS2 participates in PE, we conducted ssGSEA, which showed that sympathetic nervous system development was significantly enriched in the high-NOS2 expression group. Furthermore, Lina et al. [43] showed that levels of neuron-specific enolase and S100B, which are two cerebral biomarkers indicating neurological injury, remain elevated 1 year postpartum in PE pregnancies versus normal pregnancies. Other studies have reported that ferroptosis plays a significant role in nervous system development and nerve-related diseases [44,45,46,47]. Therefore, we speculate that NOS2 may participate in PE through ferroptosis-mediated neuronal injury. However, this hypothesis needs to be confirmed through further experimental studies.
There are some limitations of this study. The data we used to construct the diagnostic model were downloaded from the GEO database; thus, larger sample sizes should be analyzed. We found a relationship between ferroptosis-related gene signatures and immune-related biological processes. In this study, we also constructed TFs and miRNAs regulatory networks for the target genes and revealed the potential regulatory mechanisms of the ferroptosis related biomarkers in PE. Although we used RT-qPCR analysis to confirm the expression level of hub genes, further in vitro and in vivo experiments are required for validation and functional analyses.
Conclusions
In this study, WGCNA method was utilized to explore ferroptosis-related genes as biomarkers for the diagnosis of PE. We identified that NOS2 may serve as a diagnostic biomarker for PE. Our findings revealed that ferroptosis plays a role in PE etiology, thereby enhancing our knowledge of the molecular mechanisms underlying PE.
Data Availability
The GSE48424 and GSE98224 mRNA profiles were downloaded from the GEO database (https://www.ncbi.nlm.nih.gov/geo/).
Abbreviations
- AUC:
-
Area under the curve
- DEG:
-
Differentially expressed gene
- FC:
-
Fold change
- FFA:
-
Free fatty acid
- FPI:
-
Ferroptosis potential index
- GEO:
-
Gene Expression Omnibus
- miRNA:
-
MicroRNA
- NO:
-
Nitric oxide
- PE:
-
Pre-eclampsia
- ROC:
-
Receiver operating characteristic
- RT-qPCR:
-
Reverse transcription quantitative polymerase chain reaction
- ssGSEA:
-
Single-sample gene set enrichment analysis
- TF:
-
Transcription factor
- WGCNA:
-
Weighted gene co-expression network analysis
- SDS-PAGE:
-
sodium dodecyl sulfate-polyacrylamide gel electrophoresis
- PVDF:
-
polyvinylidene fluoride
- TBST:
-
Tris-buffered saline and Tween 20
- HRP:
-
horseradish peroxidase
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Acknowledgements
We would like to thank Editage (http://www.editage.cn) for English language editing.
Funding
This work was supported by a Scientific Research Project of Traditional Chinese Medicine of Guangdong Province grant (No. 20221047).
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Conception and design: Yiping Luo. Material preparation, data collection: Wenni Zhang, Huanshun Xiao and Danfeng Yu. Data analysis: Shuangming Cai and Shan Huang. Manuscript writing: Xuan Zhong and Pei Tao. All authors read and approved the final manuscript.
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The Ethics Committee of Guangdong Women and Children’s Hospital approved the study (No. 202101012), and all patients who agreed to participate in the study signed written informed consent. All the methods and procedures described in the present study were performed according to the relevant guidelines and regulations following the declaration of Helsinki.
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The authors declare no competing interests.
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Cai, S., Huang, S., Zhang, W. et al. Integrated bioinformatic analysis reveals NOS2 as a novel ferroptosis-related biomarker for pre-eclampsia. BMC Pregnancy Childbirth 23, 719 (2023). https://doi.org/10.1186/s12884-023-06051-0
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DOI: https://doi.org/10.1186/s12884-023-06051-0