Davenport, Baylea N.Wilson, Rebecca L.Jones, Helen N.
6页
查看更多>>摘要:Pregnancy complications adversely impact both mother and/or fetus throughout the lifespan. Fetal growth restriction (FGR) occurs when a fetus fails to reach their intrauterine potential for growth, it is the second highest leading cause of infant mortality, and leads to increased risk of developing non-communicable diseases in later life due 'fetal programming'. Abnormal placental development, growth and/or function underlies approximately 75% of FGR cases and there is currently no treatment save delivery, often prematurely. We previously demonstrated in a murine model of FGR that nanoparticle mediated, intra-placental human IGF-1 gene therapy maintains normal fetal growth. Multiple models of FGR currently exist reflecting the etiologies of human FGR and have been used by us and others to investigate the development of in utero therapeutics as discussed here. In addition to the in vivo models discussed herein, utilizing human models including in vitro (Choriocarcinoma cell lines and primary trophoblasts) and ex vivo (term villous fragments and placenta cotyledon perfusion) we have demonstrated robust nanoparticle uptake, transgene expression, nutrient transporter regulation without transfer to the fetus. For translational gene therapy application in the human placenta, there are multiple avenues that require investigation including syncytial uptake from the maternal circulation, transgene expression, functionality and longevity of treatment, impact of treatment on the mother and developing fetus. The potential impact of treating the placenta during gestation is high, wide-ranging across pregnancy complications, and may offer reduced risk of developing associated cardio-metabolic diseases in later life impacting at both an individual and societal level.
查看更多>>摘要:Preeclampsia is a syndromic disease of the mother, fetus, and placenta. The main limitation in early and accurate diagnosis of preeclampsia is rooted in the heterogeneity of this syndrome as reflected by diverse molecular pathways, symptoms, and clinical outcomes. Gaps in our knowledge preclude successful early diagnosis, personalized treatment, and prevention. The advent of ???omics??? technologies and systems biology approaches addresses this problem by identifying the molecular pathways associated with the underlying mechanisms and clinical phenotypes of preeclampsia. Here, we provide a brief overview on how the field has progressed, focusing on studies utilizing state-of-the-art transcriptomics and proteomics methods. Moreover, we summarize our systems biology studies involving maternal blood proteomics and placental transcriptomics, which identified early maternal and placental disease pathways and showed that their interaction influences the clinical presentation of preeclampsia. We also present an analysis of maternal blood proteomics data which revealed distinct molecular subclasses of preeclampsia and their molecular mechanisms. Maternal and placental disease pathways behind these subclasses are similar to those recently reported in studies on the placental transcriptome. These findings may promote the development of novel diagnostic tools for the distinct subtypes of preeclampsia syndrome, enabling early detection and personalized follow-up and tailored care of patients.
查看更多>>摘要:Studies have shown that the maternal nutrition during critical periods of development not only influences fetal growth but also plays a significant role in determining the risk of chronic disease in later life through developmental 'programming'. The placenta acts as a tool for 'programming' as it has the ability to adapt according to the maternal environment. There are morphological adaptations and also alterations in the expression of genes as a consequence of placental adaptations; which are critical for both placental and fetal development. Maternal nutrients especially the micronutrients (folate, vitamin B-12) of the one carbon cycle and long chain polyunsaturated fatty acids (LCPUFA) are essential for placental and fetal growth and development. They are interconnected through the one carbon cycle and play a critical role in determining pregnancy outcome. A disturbed one carbon cycle leads to altered methylation of genes which play an important role in placental development and fetal growth. This review discusses the role of maternal one carbon metabolites and its influence on placental 'programming' and long term health.
Carroll, AmberDesforges, MichelleJones, Carolyn J. P.Heazell, Alexander E. P....
7页
查看更多>>摘要:Prolonged pregnancy describes a pregnancy that progresses beyond 42 weeks' gestation (294 days). In humans, prolonged pregnancy is associated with increasing perinatal mortality, neonatal compromise and birth by Caesarean section. The underpinning reasons behind these increased risks are unknown; one potential explanation is reduced placental function due to ageing processes. This review describes the structural and functional changes seen in prolonged pregnancy in humans and in animal models. Prolonged pregnancies are associated with reduced placental growth, leading to an increase in fetal to placental weight ratio. Microscopic changes include aggregation of syncytiotrophoblast nuclei, reduced villous vascularity with a concomitant impairment of trophoblast transport processes (reduced pinocytosis); this is associated with increased evidence of oxidative stress, with downstream consequences including cellular senescence, autophagy and apoptosis; importantly many of these changes are similar to fetal growth restriction and pre-eclampsia. Thus, we argue that these observations provide evidence of ageing within the placenta, which may initially be adaptive but can become pathological leading to a reduction in placental function. This provides a biological basis for the increased risk of adverse outcomes observed in prolonged pregnancies. Greater insight into the effects and risks of placental ageing may be useful to guide clinicians on the management of prolonged pregnancies.
查看更多>>摘要:Human reproductive success relies on the intricate interplay between the developing embryo and the maternal endometrium. These highly-coordinated interactions facilitate implantation, setting in motion a series of developmental programs to establish a sustained fetal-maternal interface. Understanding endometrial function and the early human embryo-maternal dialogue is thus an important prerequisite for refining clinical approaches to alleviate implantation failure, early pregnancy loss and other obstetric complications. Yet, many mediators of implantation remain elusive. Driven by endocrine factors, interactions at the embryo-maternal interface are tightly regulated and highly complex. Coupled to the inaccessibility of the in vivo environment and scarcity of research material, studying human implantation remains exceptionally challenging. Nevertheless, the field continues to gain momentum. Cutting-edge omics technologies and high-resolution imaging have revealed important structural and functional insights into endometrial biology, while emerging bioengineering tools are enhancing our ability to model the synergies and individual features of the embryo-maternal environment. Novel in vitro platforms using human cells and embryos are considerably more accessible and easier to manipulate compared to in vivo approaches, enhancing our ability to capture specific stages of implantation. This review aims to showcase current and emerging technologies used to study human endometrial biology and the early embryo-maternal interface, including single cell omics approaches, bioengineered endometrial models and embryo-endometrium co-culture platforms. We highlight the value of these approaches and provide our perspective on the current challenges faced by the field. Recognizing the physiological scope of these emerging technologies will be key for utilizing their full potential and driving future innovation.
查看更多>>摘要:The human placenta is a highly specialized organ that is responsible for housing, protecting, and nourishing the fetus across gestation. The placenta is essential as it functions among other things as the liver, lungs, and gut while also playing key immunological and endocrine roles. The structure and transport capacity of this temporary organ must evolve as gestation progresses while also adapting to possible alterations in maternal nutrient availability. All nutrients needed by the developing fetus must cross the human placenta. Iron (Fe) is one such nutrient that is both integral to placental function and to successful pregnancy outcomes. Iron deficiency is among the most common nutrient deficiencies globally and pregnant women are particularly vulnerable. Data on the partitioning of Fe between the mother, placenta and fetus are evolving yet many unanswered questions remain. Hepcidin, erythroferrone and erythropoietin are regulatory hormones that are integral to iron homeostasis. The mother, fetus and placenta independently produce these hormones, but the relative function of these hormones varies in each of the maternal, placental, and fetal compartments. This review will summarize basic aspects of Fe physiology in pregnant women and the maternal, fetal, and placental adaptations that occur to maintain Fe homeostasis at this key life stage.
查看更多>>摘要:Correct establishment of the placenta is critical to the success of a pregnancy, but many of the key events take place during or shortly after implantation and are inaccessible for study. This inaccessibility, coupled with the lack of a suitable preclinical animal model, means that knowledge of human early placental development and function is extremely limited. Hence, the first trimester is often referred to as the ???black box??? of pregnancy. However, recent advances in the derivation of trophoblast stem cells and organoid cultures of the trophoblast and endometrium are opening new opportunities for basic and translational research, providing for the first time cells that faithfully replicate their tissue of origin and proliferate and differentiate in culture in a stable and reproducible manner. These cells are valuable new tools for investigating cell-lineage differentiation and maternal-fetal interactions, but become even more powerful when combined with advances in bioengineering, microfabrication and microfluidic technologies. Assembloids of the endometrium comprising various cell types as model systems to investigate events at implantation, and placentas-on-a-chip for the study of nutrient transfer or drug screening are just two examples. This is a rapidly advancing field that may usher in more personalised approaches to infertility and pregnancy complications. Many of the developments are still at the proof-of principle phase, but with continued refinement they are likely to shed important light on events that are fundamental to our reproduction as individuals and as a species, yet for ethical reasons are hidden from view.
Guettler, JacquelineForstner, DesireeGauster, Martin
7页
查看更多>>摘要:In human pregnancy, maternal platelet counts decrease with each trimester, reaching a reduction by approximately ten percent at term in uncomplicated cases and recover to the levels of the non-pregnant state a few weeks postpartum. The time when maternal platelets start to occur in the early human placenta most likely coincides with the appearance of loosely cohesive endovascular trophoblast plugs showing capillary-sized channels by mid first trimester. At that time, platelets accumulate in intercellular gaps of anchoring parts of trophoblast columns and start to adhere to the surface of placental villi and the chorionic plate. This is considered as normal process that contributes to placenta development by acting on both the extravillous-and the villous trophoblast compartment. Release of platelet cargo into intercellular gaps of anchoring cell columns may affect partial epithelial-to-mesenchymal transition and invasiveness of extravillous trophoblasts as well as deposition of fibrinoid in the basal plate. Activation of maternal platelets on the villous surface leads to perivillous fibrin-type fibrinoid deposition, contributing to the shaping of the developing placental villi and the intervillous space. In contrast, excess platelet activation at the villous surface leads to deregulation of the endocrine activity, sterile inflammation and local apoptosis of the syncytiotrophoblast. Platelets and their released cargo are adapted to pregnancy, and may be altered in high-risk pregnancies. Identification of different maternal platelet sub populations, which show differential procoagulant ability and different response to anti-platelet therapy, are promising new future directions in deciphering the role of maternal platelets in human placenta physiology.
NSTL
Elsevier