Search Results (61)

This study investigated the metabolic mechanisms driving physiological functional remodeling in RFM by analyzing plasma biochemical parameters and metabolomic profiles at key peripartum timepoints (21 and 7 d prepartum and 4 h postpartum), integrated with placental and fetal membrane metabolic characteristics. The results revealed that RFM cows exhibited significant negative energy balance (NEB) as early as 21 days before parturition, characterized by elevated plasma levels of non-esterified fatty acids, β-hydroxybutyrate, and malondialdehyde, alongside reduced activity of antioxidant enzymes (GSH-Px, CAT) (p ≤ 0.05). Metabolomic analysis demonstrated persistent lipid metabolism dysregulation, amino acid imbalance, and nucleotide metabolism disturbances in RFM cows from 21 days prepartum to 4 h postpartum, indicating premature mobilization of adipose and muscle tissues. Further metabolomic analyses of the placenta and fetal membranes confirmed that metabolic dysfunction compromises energy supply during parturition, adversely affecting immune homeostasis and extracellular matrix degradation in the placenta and fetal membranes of RFM dairy cows. These physiological dysfunctions have the potential to impede the timely expulsion of fetal membranes after calving. In conclusion, RFM is closely associated with early-onset metabolic dysfunction during the periparturient period, where insufficient energy supply due to NEB, oxidative stress, and immune-endocrine disruptions collectively impair normal fetal membrane detachment. Full article

Gestational diabetes mellitus (GDM) is a multifactorial metabolic disorder arising from impaired insulin sensitivity and altered maternal–fetal energy regulation. Beyond classical mechanisms involving β-cell dysfunction and pregnancy-induced insulin resistance, emerging evidence suggests a bidirectional interaction between the maternal gut microbiota and the placenta, forming a dynamic placenta–gut axis. Microbial dysbiosis alters levels of metabolites, inflammatory mediators, and bile acids, which influence placental signaling, trophoblast metabolism, immune activation, and nutrient transport. Conversely, the placenta secretes hormones, cytokines, lipids, and exosomal miRNAs that shape maternal metabolism and potentially modulate the gut microbiota. This review synthesizes current mechanistic insights underlying the placenta–gut microbiota axis in GDM, describes immune and metabolic crosstalk, and highlights therapeutic opportunities targeting this inter-organ communication system. Addressing these interactions may advance precision strategies for managing GDM and improving outcomes across generations. Full article

Lipid accumulation disrupts mitochondrial dynamics, leading to dysfunctional energy metabolism and increased oxidative stress. However, the relationship between mitochondrial dynamics and ovarian function in therapeutic contexts is still not fully elucidated. Therefore, the objective of this study was to demonstrate whether increased carnitine palmitoyltransferase 1A (CPT1A) expression induced by placenta-derived mesenchymal stem cells (PD-MSCs) improves ovarian function in ovaries of a lipid toxicity-induced rat model by regulating lipid metabolism and mitochondrial dynamics. A rat model of injury was induced through intraperitoneal administration of thioacetamide (TAA) for 12 weeks. During the 8th week of induction, PD-MSCs (2 × 10⁶ cells) were transplanted via the tail vein. Initially, we examined the engraftment of PD-MSCs. The inflammatory response (e.g., IL-6, TNFα) and apoptosis (e.g., LDH levels, TUNEL assay) were significantly increased in the non-transplanted (NTx) group compared to the normal group; however, they were significantly decreased in the transplanted (Tx) group compared to the NTx group (* p < 0.05). Additionally, oxidative stress was attenuated through the regulation of mitochondrial dynamics, including the expression of DRP1, ATP5B, and PGC1α, in the Tx group compared to the NTx group (* p < 0.05). In the NTx group, abnormally accumulated lipid droplets were observed due to dysfunctional mitochondria, whereas in the Tx group, the accumulation of lipid droplets and the expression of CPT1A were significantly comparable to those in the normal group (* p < 0.05). The levels of the steroidogenesis markers (e.g., CYP11A1 and HSD3β1) were decreased in the NTx group compared to the normal group and increased in the Tx group compared to the NTx group (* p < 0.05). The levels of sex hormone and follicular development were protected in the Tx group compared to the NTx group. Furthermore, cocultivation of PD-MSCs with etomoxir (CPT1A inhibitor)-treated primary theca cells increased the expression of steroidogenesis. In conclusion, PD-MSCs improve ovarian function in TAA-induced injury by reducing lipid accumulation and oxidative stress through the regulation of lipid metabolism and mitochondrial dynamics. The upregulation of CPT1A and related mitochondrial proteins contributes to enhanced steroidogenesis and restoration of ovarian homeostasis. These findings offer new insights into the application of stem cell therapies for reproductive medicine. Full article

Developmental programming, shaped by environmental and lifestyle stressors during prenatal life, is increasingly recognized as a major contributor to non-communicable diseases (NCDs) later in life. Oxidative stress, one of key mechanisms linking these stressors to fetal metabolomic reprogramming and disease pathogenesis, leaves measurable metabolomic signatures that reflect disrupted redox balance. Alterations in glucose, lipid, and amino acid metabolism and antioxidant response could reveal the main pathways driving NCD development. This review summarizes epidemiological studies that have investigated biochemical responses of the prenatal exposure to metals, air pollution, and tobacco smoke and e-cigarette vapor in maternal–placental–fetal compartments using a metabolomic approach. Summarized studies indicate that maternal exposure to metals primarily disrupts amino acid pathways related to one-carbon metabolism, glutathione synthesis, and oxidative stress defense, while air pollution, particularly fine particulate matter, mainly affects lipid oxidation, fatty acid β-oxidation, and amino acid and carbohydrate metabolism. Tobacco smoke and e-cigarette vapor induce widespread disturbances involving reduced citric acid cycle intermediates, altered acylcarnitines and phospholipids, and impaired antioxidant capacity, collectively promoting oxidative damage and inflammatory signaling. The identification of these metabolome alterations might contribute to a deeper understanding of the toxicity and biological impact of environmental stressors on offspring health. These results may eventually lead to the identification of early biomarkers and to the development of therapeutic strategies aimed at reducing NCD risk. Full article

Somatic cell nuclear transfer (SCNT) or cloning technology is widely used in agriculture and biomedicine. However, the application of this technology is limited by the low developmental competence of cloned embryos or fetuses, which frequently exhibit abnormal development of trophoblast cells or placentas. The purpose of this study was to investigate the possible causes of the erroneous placental development of SCNT-derived pig fetuses. The placental transcriptomic and lipidomic profiles were compared between 30-day-old SCNT- and artificial insemination (AI)-produced pig fetuses. Differentially expressed lipid metabolites between two groups of placentas were selected to test their effects on porcine trophoblast cell activity. The results showed that SCNT placentas exhibit impaired lipid metabolism and function. The level of a metabolite, lysophosphatidylcholine (LPC), in the glycerophospholipid metabolism pathway was substantially increased in SCNT placentas, compared with AI placentas. The elevation in LPC content may lead to impaired placental development in cloned pig fetuses, as LPC inhibited the proliferation and migration of porcine trophoblast cells. This study discovers a main cause of erroneous development of cloned pig fetuses, which will be beneficial for understanding the regulation of SCNT embryo development, as well as developing new methods to improve the efficiency of pig cloning. Full article

Background/Objectives: Individuals with metabolically healthy obesity (MHO) and metabolically unhealthy obesity (MUO) in pregnancy are two distinct cardiometabolic populations, each potentially necessitating alternative clinical management. However, our understanding of the unique physiological effects of uncomplicated MHO on fetoplacental growth and metabolism remains limited. In this study, we aimed to identify changes in placental morphology and metabolites associated with maternal obesity, independent of pregnancy-related cardiometabolic complications. Methods: Placentae from women with a prepregnancy body mass index (BMI) < 25 kg/m² (control; n = 15) and women with MHO (prepregnancy BMI > 30 kg/m² with no cardiometabolic diseases; n = 15) were analyzed for indices of placental growth and untargeted metabolomics. Complementary assessments were conducted on proinflammatory genes and antioxidant defense system genes, proteins, and enzymes, along with lipid peroxidation markers. Results: Clear placentomegaly without histopathological changes was observed in uncomplicated MHO pregnancies. The metabolite 3-aminoisobutanoic acid emerged as the top-ranked feature distinguishing placentae from MHO individuals from control placentae, and changes in the cysteine, methionine, and vitamin B6 metabolism pathways were among the most distinct differences identified. Conclusions: These findings illustrate an altered placental morphology and metabolomic profile specific to uncomplicated MHO, offering new insights into how obesity, without cardiometabolic complications, may influence fetoplacental growth and metabolism. They may also represent a crucial first step towards marker identification for MHO pregnancy and underscore the importance of alternative care pathways when obesity is present but metabolic comorbidities are absent. Full article

Gestational complications, such as preeclampsia and gestational diabetes mellitus (GDM), pose significant risks to maternal and fetal health and increase long-term cardiovascular disease risk in offspring. This review aims to synthesize current knowledge on the roles of ferroptosis and neutrophil extracellular trap formation (NETosis)—two regulated cell death pathways—in these pregnancy-related conditions. We performed a comprehensive analysis of preclinical and clinical studies that investigate the involvement of dysregulated iron metabolism, oxidative stress, inflammation, and endothelial dysfunction mediated by ferroptosis and NETosis in gestational pathologies. Evidence indicates that disturbances in maternal iron homeostasis and enhanced formation of lipid peroxides and NETs contribute to placental dysfunction and systemic inflammation, exacerbating disease severity. Therapeutic strategies targeting these pathways are emerging but require further validation. Our review also identifies key gaps in mechanistic understanding, biomarker development, and translational research needs. We conclude that modulation of ferroptosis and NETosis offers promising avenues for improving diagnosis and treatment of pregnancy complications, though carefully designed clinical studies are essential to confirm their clinical utility and safety. Full article

During pregnancy, the regulation of autophagy and ferroptosis dynamically supports placental development and fetal health. Both processes—autophagy, clearing damaged organelles to maintain placental function, and ferroptosis, driven by iron-dependent lipid peroxidation—are involved in pathological conditions such as preeclampsia. Emerging evidence suggests that gut microbiota-derived metabolites act as key regulators of this balance, yet their specific roles across different trimesters remain unclear. This review compiles evidence on how gut microbiota metabolites, like short-chain fatty acids and trimethylamine N-oxide, serve as trimester-specific modulators of the autophagy–ferroptosis balance during pregnancy. We explain how these metabolites influence pregnancy outcomes by regulating placental autophagy and ferroptosis. Furthermore, we explore potential diagnostic and therapeutic approaches for pregnancy complications, focusing on metabolite-based biomarkers and interventions that target microbial–metabolic interactions. Full article

Preeclampsia (PE) is a pregnancy-specific hypertensive disorder characterized by systemic inflammation, endothelial dysfunction, and placental insufficiency. While inadequate trophoblast invasion and impaired spiral artery remodeling have long been recognized as central to its pathogenesis, emerging evidence underscores the critical roles of dysregulated iron metabolism and its crosstalk with immune responses, particularly macrophage-mediated inflammation, in driving PE development. This review systematically explores the dynamic changes in iron metabolism during pregnancy, including increased maternal iron demand, placental iron transport mechanisms, and the molecular regulation of placental iron homeostasis. We further explore the contribution of ferroptosis, an iron-dependent form of regulated cell death driven by lipid peroxidation, to trophoblast dysfunction and pregnancy-related diseases, including PE. Macrophages, pivotal immune regulators at the maternal–fetal interface, exhibit distinct polarization states that shape tissue remodeling and immune tolerance. We outline their origin, distribution, and polarization in pregnancy, and emphasize their aberrant phenotype and function in PE. The bidirectional crosstalk between iron and macrophages is also dissected: iron shapes macrophage polarization and function, while macrophages reciprocally modulate iron homeostasis. Notably, excessive reactive oxygen species (ROS) and pro-inflammatory cytokines secreted by M1-polarized macrophages may exacerbate trophoblast ferroptosis, amplifying placental injury. Within the context of PE, we delineate how iron overload and macrophage dysfunction synergize to potentiate placental inflammation and oxidative stress. Key iron-responsive immune pathways, such as the HO-1/hepcidin axis and IL-6/TNF-α signaling, are discussed in relation to disease severity. Finally, we highlight promising therapeutic strategies targeting the iron–immune axis, encompassing three key modalities—iron chelation therapy, precision immunomodulation, and metabolic reprogramming interventions—which may offer novel avenues for PE prevention and treatment. Full article

Background: Prenatal alcohol exposure (PAE) can reduce fetal growth and cause neurodevelopmental disability. Prenatal choline supplements attenuate PAE-induced behavioral and growth deficits; however, the underlying mechanisms are unknown. Alcohol alters nutrient metabolism and potentially increases nutrient needs. Here, we investigate how alcohol affects choline metabolism in the maternal–fetal dyad and the role of supplemental choline. Methods: Pregnant C57BL/6J mice were assigned to one of four groups: alcohol-exposed (3 g/kg alcohol/day) or control +/− 100 mg/kg choline daily from embryonic day (E)8.5–17.5. We performed an exploratory hypothesis-generating analysis of targeted metabolomics on choline-related metabolites in the maternal liver, plasma, placenta, and fetal brain at E17.5 and Spearman correlation analyses to determine their association with gestational and fetal growth outcomes. Results: Although choline levels were largely unaffected by alcohol or choline, alcohol increased many lipid products in the CDP–choline pathway; this was not normalized by choline. Alcohol increased placental CDP–ethanolamine and reduced the maternal hepatic SAM/SAH ratio as well as dimethylglycine and the serine/glycine ratio across the dyad, suggesting a functional insufficiency in methyl donor pools. These outcomes were rescued by supplemental choline. Correlation analyses among choline metabolites and fetal growth outcomes suggest that maternal plasma methionine, serine, and the serine/glycine ratio may be predictive of maternal–fetal choline status. Conclusions: The increased hepatic lipid synthesis that characterizes chronic alcohol exposure may draw choline into phospholipid biosynthesis at the expense of its use as a methyl donor. We propose that PAE increases choline needs, and that its supplementation is necessary to fulfill these competing demands for lipid and methyl use. Full article

Introduction: What if porcine placental extract (PPE) could combat post-menopausal weight gain and lipid imbalances without the side effects of traditional hormone treatments? The menopause marks a critical shift in women’s health, with declining estrogen levels driving increased risks of obesity, metabolic dysfunction, and cardiovascular disease. While hormone replacement therapy remains a common intervention, concerns over its long-term safety have intensified the search for safer alternatives. Objectives: This study aims to explore the metabolic effects of porcine placental extract (PPE) by using an ovariectomized (OVX) rat model to mimic the hormonal landscape of the menopause. Methods: Twenty OVX Wistar rats were assigned to either a control group receiving phosphate-buffered saline or a PPE-treated group given intraperitoneal PPE injections for two weeks. Results: Remarkably, the PPE-treated rats showed significantly lower body weights than the controls. Biochemical analysis revealed that the PPE-treated rats had improved lipid profiles, involving lower total cholesterol and triglyceride levels. Histological examinations of the PPE-treated rats showed no adverse changes in the uterus or mammary glands. Conclusions: These results highlight PPE’s potential as a non-hormonal, tissue-safe intervention for combating weight gain and lipid imbalances in post-menopausal conditions. By promoting lipolysis without impacting reproductive health or muscle mass, PPE opens the door to new possibilities for managing post-menopausal metabolic health. However, further research is needed to determine its long-term efficacy. Full article

Preeclampsia (PE) is a severe hypertensive pregnancy disorder characterized by endothelial dysfunction, placental ischemia and oxidative stress; however, reliable non-invasive biomarkers for early detection are limited. In this study, untargeted solid-phase microextraction with gas chromatography–mass spectrometry (SPME-GC-MS) was used to analyze volatile organic compounds in the urine of 45 women with PE and 46 healthy controls. Among the 29 metabolites identified, hexadecanal—a product of lipid peroxidation and sphingolipid metabolism—was found to be the most significant, with an area under the receiver operating characteristic (ROC) curve of 0.618, highlighting its diagnostic potential. This result emphasizes the role of hexadecanal in oxidative stress and placental dysfunction, which are central to the pathophysiology of PE. The results support hexadecanal as a potential non-invasive biomarker while demonstrating the efficacy of SPME-GC-MS in identifying metabolic disorders associated with PE, paving the way for further research to confirm its clinical utility for early diagnosis and risk assessment. Full article

Fetal growth restriction (FGR) is a disorder defined as the failure of a fetus to achieve its full biological development potential due to decreased placental function, which can be attributed to a range of reasons. FGR is linked to negative health outcomes during the perinatal period, including increased morbidity and mortality. Long-term health problems, such as impaired neurological and cognitive development, as well as cardiovascular and endocrine diseases, have also been found in adulthood. Aspirin administered prophylactically to high-risk women can effectively prevent FGR. FGR pregnancy care comprises several steps, including the weekly assessment of several blood vessels using Doppler measurements, amniotic fluid index (AFI), estimated fetal weight (EFW), cardiotocography (CTG), as well as delivery by 37 weeks. Pregnancy is a complex condition characterized by metabolic adjustments that guarantee a consistent provision of vital metabolites allowing the fetus to grow and develop. The lipoprotein lipid physiology during pregnancy has significant consequences for both the fetus and baby, and for the mother. In the course of a typical pregnancy, cholesterol levels increase by roughly 50%, LDL-C (low-density lipoprotein cholesterol) levels by 30–40%, HDL-C by 25% (high-density lipoprotein cholesterol). Typically, there is also a 2- to 3-fold increase in triglycerides. Low maternal blood cholesterol levels during pregnancy are linked to a decrease in birth weight and an increased occurrence of microcephaly. FGR impacts the placenta during pregnancy, resulting in alterations in lipid metabolism. Research has been undertaken to distinguish variations in protein expression between normal placentas and those impacted by FGR. This can aid in comprehending the fundamental pathogenic mechanisms of FGR and perhaps pave the way for the creation of novel diagnostic and treatment methods. Commonly employed approaches for detecting and analyzing variations in placental proteomes include mass spectrometry, bioinformatic analysis, and various proteomic techniques. Full article

(1) Background: Retained fetal membranes (RFM) in cattle negatively impact reproduction, calving intervals, and health. This study examined OS markers and fatty acid profiles in Romanian Spotted cattle, comparing cows with normal parturition to those with RFM. Over 9 weeks, serum samples were collected from 22 cows (7 with RFM, 15 normal) at intervals before and after parturition. Placental tissues were also analyzed. The aim was to identify OS biomarkers that predict RFMs, track changes over time, and assess their impact on the placental fatty acid profile. (2) Methods: Samples were analyzed for superoxide dismutase (SOD), catalase (CAT), malondialdehyde (MDA), and total antioxidant capacity (TAC). Placental fatty acids were profiled using gas chromatography–mass spectrometry. (3) Results: SOD and CAT activities increased in cows with retained fetal membranes (RFM) before parturition (SOD: p < 0.001, RFM 404.601 ± 20.941 vs. NP 339.101 ± 44.911; CAT: p < 0.01, RFM 121.132 ± 14.831 vs. NP 96.070 ± 2.397), indicating OS. However, significant decreases during labor suggested weakened antioxidant defenses. Total antioxidant capacity (TAC) peaked during parturition in RFM cows (p < 0.0001, 38.780 ± 3.727 vs. 11.150 ± 1.555), signaling heightened stress. Additionally, MDA levels increased before parturition (p < 0.001, RFM 8.424 ± 1.894 vs. NP 3.807 ± 0.484), confirming lipid peroxidation. RFM cows also exhibited higher levels of saturated fatty acids and lower monounsaturated fatty acids, pointing to metabolic stress. (4) Conclusions: This study highlights the role of OS and fatty acid imbalances in RFMs, suggesting potential strategies to improve reproductive outcomes by managing OS. Full article

The placenta is a vital organ in bovine reproduction, crucial for blood supply, nutrient transport, and embryonic development. It plays an essential role in the intrauterine growth of calves. However, the molecular mechanisms governing placental function in calves remain inadequately understood. Methods: We established transcriptome and proteome databases for low-birth-weight (LB) and high-birth-weight (HB) calf placentae, identifying key genes and proteins associated with birth weight through bioinformatics analyses that included functional enrichment and protein–protein interactions (PPIs). Both mRNA and protein levels were validated. Results: A total of 1494 differentially expressed genes (DEGs) and 294 differentially expressed proteins (DEPs) were identified when comparing the LB group to the HB group. Furthermore, we identified 53 genes and proteins exhibiting significant co-expression across both transcriptomic and proteomic datasets; among these, 40 were co-upregulated, 8 co-downregulated, while 5 displayed upregulation at the protein level despite downregulation at the mRNA level. Functional enrichment analyses (GO and KEGG) and protein–protein interaction (PPI) analysis indicate that, at the transcriptional level, the primary factor contributing to differences in calf birth weight is that the placenta of the high-birth-weight (HB) group provides more nutrients to the fetus, characterized by enhanced nutrient transport (SLC2A1 and SLC2A11), energy metabolism (ACSL1, MICALL2, PAG2, COL14A1, and ELOVL5), and lipid synthesis (ELOVL5 and ELOVL7). In contrast, the placenta of the low-birth-weight (LB) group prioritizes cell proliferation (PAK1 and ITGA3) and angiogenesis. At the protein level, while the placentae from the HB group exhibit efficient energy production and lipid synthesis, they also demonstrate reduced immunity to various diseases such as systemic lupus erythematosus and bacterial dysentery. Conversely, the LB group placentae excel in regulating critical biological processes, including cell migration, proliferation, differentiation, apoptosis, and signal transduction; they also display higher disease immunity markers (COL6A1, TNC CD36, CD81, Igh-1a, and IGHG) compared to those of the HB group placentae. Co-expression analysis further suggests that increases in calf birth weight can be attributed to both high-efficiency energy production and lipid synthesis within the HB group placentae (ELOVL5, ELOVL7, and ACSL1), alongside cholesterol biosynthesis and metabolic pathways involving CYP11A1 and CYP17A1. Conclusion: We propose that ELOVL5, ELOVL7, ACSL1, CYP11A1, and CYP17A1 serve as potential protein biomarkers for regulating calf birth weight through the modulation of the fatty acid metabolism, lipid synthesis, and cholesterol levels. Full article