ABSTRACT
Liver fibrosis results from many chronic injuries and may often progress to cirrhosis and hepatocellular carcinoma (HCC). In fact, up to 90% of HCC arise in a cirrhotic liver. Conversely, stress is implicated in liver damage, worsening disease outcome. Hence, stress could play a role in disrupting liver homeostasis, a concept that has not been fully explored. Here, in a murine model of TAA-induced liver fibrosis we identified nerve growth factor (NGF) to be a crucial regulator of the stress-induced fibrogenesis signaling pathway as it activates its receptor p75 neurotrophin receptor (p75NTR), increasing liver damage. Additionally, blocking the NGF decreased liver fibrosis whereas treatment with recombinant NGF accelerated the fibrotic process to a similar extent than stress challenge. We further show that the fibrogenesis induced by stress is characterized by specific changes in the hepatoglycocode (increased ß1,6GlcNAc-branched complex N-glycans and decreased core 1 O-glycans expression) which are also observed in patients with advanced fibrosis compared to patients with a low level of fibrosis. Our study facilitates an understanding of stress-induced liver injury and identify NGF signaling pathway in early stages of the disease, which contributes to the established fibrogenesis.
Subject(s)
Gene Expression Regulation , Liver Cirrhosis/pathology , Nerve Growth Factor/metabolism , Polysaccharides/metabolism , Receptors, Nerve Growth Factor/metabolism , Stress, Physiological , Thioacetamide/toxicity , Animals , Liver Cirrhosis/chemically induced , Liver Cirrhosis/genetics , Liver Cirrhosis/metabolism , Male , Mice , Mice, Inbred C57BL , Nerve Growth Factor/genetics , Receptors, Nerve Growth Factor/geneticsABSTRACT
Adverse intrauterine conditions may cause fetal growth restriction (FGR), a pregnancy complication frequently linked to perinatal morbidity and mortality. Although many studies have focused on FGR, the pathophysiological processes underlying this disorder are complex and incompletely understood. We have recently determined that galectin-3 (gal-3), a ß-galactoside-binding protein, regulates pregnancy-associated processes, including uterine receptibility, maternal vascular adaptation and placentation. Because gal-3 is expressed at both sides of the maternal-fetal interface, we unraveled the contribution of maternal- and paternal-derived gal-3 on fetal-placental development in the prenatal window and its effects on the post-natal period. Deficiency of maternal gal-3 induced maternal gut microbiome dysbiosis, resulting in a sex-specific fetal growth restriction mainly observed in female fetuses and offspring. In addition, poor placental metabolic adaptions (characterized by decreased trophoblast glycogen content and insulin-like growth factor 2 (Igf2) gene hypomethylation) were only associated with a lack of maternal-derived gal-3. Paternal gal-3 deficiency caused compromised vascularization in the placental labyrinth without affecting fetal growth trajectory. Thus, maternal-derived gal-3 may play a key role in fetal-placental development through the gut-placenta axis.
Subject(s)
Fetal Growth Retardation , Galectin 3 , Placenta , Fetal Growth Retardation/metabolism , Fetal Growth Retardation/genetics , Pregnancy , Female , Animals , Placenta/metabolism , Mice , Galectin 3/metabolism , Galectin 3/deficiency , Galectin 3/genetics , Male , Gastrointestinal Microbiome , Mice, Inbred C57BL , Humans , Fetal Development , Insulin-Like Growth Factor II/metabolism , Insulin-Like Growth Factor II/genetics , Insulin-Like Growth Factor II/deficiency , Trophoblasts/metabolismABSTRACT
Placental abnormalities cause impaired fetal growth and poor pregnancy outcome (e.g. preeclampsia [PE]) with long-lasting consequences for the mother and offspring. The molecular dialogue between the maternal niche and the developing placenta is critical for the function of this organ. Galectin-1 (gal-1), a highly expressed glycan-binding protein at the maternal-fetal interface, orchestrates the maternal adaptation to pregnancy and placenta development. Down-regulation or deficiency of gal-1 during pregnancy is associated with the development of PE; however, the maternal- and placental-derived gal-1 contributions to the disease onset are largely unknown. We demonstrate that lack of gal-1 imposes a risk for PE development in a niche-specific manner, and this is accompanied by a placental dysfunction highly influenced by the absence of maternal-derived gal-1. Notably, differential placental glycosylation through the Sda-capped N-glycans dominates the invasive trophoblast capacity triggered by maternal-derived gal-1. Our findings show that gal-1 derived from the maternal niche is essential for healthy placenta development and indicate that impairment of the gal-1 signaling pathway within the maternal niche could be a molecular cause for maternal cardiovascular maladaptation during pregnancy.
ABSTRACT
Galectin-1 (gal-1), a member of a family of evolutionarily conserved glycan-binding proteins, is differentially expressed at the feto-maternal interface and appears to be functionally polyvalent, with a wide range of biological activities. However, the contributions of maternal and/or feto-placental gal-1 to the signaling networks promoting a healthy pregnancy are still being elucidated. This chapter discusses the methods commonly employed to study the maternal or feto-placental contribution of gal-1 during pregnancy in mice. The methods described here can be used to decipher the specific role of each source, e.g., maternal and/or feto-placental derived gal-1 in the orchestration of pregnancy-associated processes.
Subject(s)
Galectin 1 , Placenta , Pregnancy , Animals , Family , Female , Galectin 1/genetics , Galectin 1/metabolism , Mice , Placenta/metabolism , Pregnancy/metabolism , Pregnancy OutcomeABSTRACT
Pregnancies carried by women with chronic hypertension are at increased risk of superimposed preeclampsia, but the placental pathways involved in disease progression remain poorly understood. In this study, we used the stroke-prone spontaneously hypertensive rat (SHRSP) model to investigate the placental mechanisms promoting superimposed preeclampsia, with focus on cellular stress and its influence on galectin-glycan circuits. Our analysis revealed that SHRSP placentas are characterized by a sustained activation of the cellular stress response, displaying significantly increased levels of markers of lipid peroxidation (i.e., thiobarbituric acid reactive substances (TBARS)) and protein nitration and defective antioxidant enzyme expression as early as gestation day 14 (which marks disease onset). Further, lectin profiling showed that such redox imbalance was associated with marked alterations of the placental glycocode, including a prominent decrease of core 1 O-glycan expression in trophoblasts and increased decidual levels of sialylation in SHRSP placentas. We also observed significant changes in the expression of galectins 1, 3 and 9 with pregnancy progression, highlighting the important role of the galectin signature as dynamic interpreters of placental microenvironmental challenges. Collectively, our findings uncover a new role for the glycoredox balance in the pathogenesis of superimposed preeclampsia representing a promising target for interventions in hypertensive disorders of pregnancy.
Subject(s)
Disease Progression , Placenta/metabolism , Polysaccharides/metabolism , Pre-Eclampsia/metabolism , Pre-Eclampsia/pathology , Animals , Antioxidants/metabolism , Disease Models, Animal , Female , Galectins/metabolism , Glycosylation , Models, Biological , Oxidation-Reduction , Phenotype , Pregnancy , Rats, Inbred SHR , Rats, Inbred WKY , Stress, Physiological , Time FactorsABSTRACT
PROBLEM: Proper placental development is pivotal to ensure healthy pregnancy outcomes. Among the multiple cellular mechanisms involved in the orchestration of this process, little is known on the role of alternative splicing events in the modulation of trophoblast cell biology. Here, we evaluated the expression of the alternative splicing regulator Rbfox2 in the pre- and post-placentation period in mouse pregnancies in both healthy and pathological settings. METHOD OF STUDY: Immunofluorescence analysis of Rbfox2 expression in mouse implantation sites collected during the pre-placentation period (E5-E7) and post-placentation (E13). RESULTS: We identified a progressive increase of Rbfox2 levels throughout the peri-implantation period with a shift from a cytoplasmatic expression on E5-E6 to a predominantly nuclear expression on E7, together with a prominent expression of this factor in both subcellular compartments of the primitive placenta. Our results further showed that in contrast to healthy gestations, Rbfox2 expression decreased in preeclamptic models during the post-placentation period. Finally, we further demonstrated enhanced expression of Rbfox2 proteins in allogeneic pregnancy compared to syngeneic models. CONCLUSIONS: Our findings uncover a novel role for Rbfox2-controlled splicing events in the modulation of trophoblast function, with potential implications for the pathogenesis of preeclampsia and other pregnancy complications originated from defective placentation.
Subject(s)
Gene Expression Regulation , Placentation/genetics , Pre-Eclampsia/metabolism , RNA Splicing Factors/metabolism , Animals , Disease Models, Animal , Female , Mice , Placenta/metabolism , Pre-Eclampsia/genetics , Pregnancy , RNA Splicing Factors/genetics , Trophoblasts/metabolismABSTRACT
Placental hypoperfusion and hypoxia are key drivers in complications during fetal development such as fetal growth restriction and preeclampsia. In order to study the mechanisms of disease in mouse models, the development of quantitative biomarkers of placental hypoxia is a prerequisite. The goal of this exploratory study was to establish a technique to noninvasively characterize placental partial pressure of oxygen (PO2) in vivo in the Lgals1 (lectin, galactoside-binding, soluble, 1) deficient mouse model of preeclampsia using fluorine magnetic resonance imaging. We hypothesized a decrease in placental oxygenation in knockout mice. Wildtype and knockout animals received fluorescently labeled perfluoro-5-crown-15-ether nanoemulsion i.v. on day E14-15 during pregnancy. Placental PO2 was assessed via calibrated 19F MRI saturation recovery T1 mapping. A gas challenge with varying levels of oxygen in breathing air (30%, 60% and 100% O2) was used to validate that changes in oxygenation can be detected in freely breathing, anesthetized animals. At the end of the experiment, fluorophore-coupled lectin was injected i.v. to label the vasculature for histology. Differences in PO2 between breathing conditions and genotype were statistically analyzed with linear mixed-effects modeling. As expected, a significant increase in PO2 with increasing oxygen in breathing air was found. PO2 in Lgals1 knockout animals was decreased but this effect was only present at 30% oxygen in breathing air, not at 60% and 100%. Histological examinations showed crossing of the perfluorocarbon nanoemulsion to the fetal blood pool but the dominating contribution of 19F MR signal is estimated at > 70% from maternal plasma based on volume fraction measurements of previous studies. These results show for the first time that 19F MRI can characterize oxygenation in mouse models of placental malfunction.
Subject(s)
Galectin 1/genetics , Magnetic Resonance Imaging/methods , Oxygen/metabolism , Placenta/metabolism , Algorithms , Animals , Crown Ethers/metabolism , Disease Models, Animal , Female , Fluorine/metabolism , Galectin 1/deficiency , Hypoxia , Mice, 129 Strain , Mice, Knockout , Partial Pressure , Phenotype , Pregnancy , RespirationABSTRACT
Immune cells [e. g., dendritic cells (DC) and natural killer (NK) cells] are critical players during the pre-placentation stage for successful mammalian pregnancy. Proper placental and fetal development relies on balanced DC-NK cell interactions regulating immune cell homing, maternal vascular expansion, and trophoblast functions. Previously, we showed that in vivo disruption of the uterine NK cell-DC balance interferes with the decidualization process, with subsequent impact on placental and fetal development leading to fetal growth restriction. Glycans are essential determinants of reproductive health and the glycocode expressed in a particular compartment (e.g., placenta) is highly dependent on the cell type and its developmental and pathological state. Here, we aimed to investigate the maternal and placental glycovariation during the pre- and post-placentation period associated with disruption of the NK cell-DC dynamics during early pregnancy. We observed that depletion of NK cells was associated with significant increases of O- and N-linked glycosylation and sialylation in the decidual vascular zone during the pre-placental period, followed by downregulation of core 1 and poly-LacNAc extended O-glycans and increased expression of branched N-glycans affecting mainly the placental giant cells and spongiotrophoblasts of the junctional zone. On the other hand, expansion of DC induced a milder increase of Tn antigen (truncated form of mucin-type O-glycans) and branched N-glycan expression in the vascular zone, with only modest changes in the glycosylation pattern during the post-placentation period. In both groups, this spatiotemporal variation in the glycosylation pattern of the implantation site was accompanied by corresponding changes in galectin-1 expression. Our results show that pre- and post- placentation implantation sites have a differential glycopattern upon disruption of the NK cell-DC dynamics, suggesting that immune imbalance early in gestation impacts placentation and fetal development by directly influencing the placental glycocode.