The transposable element-derived transcript of LIN28B has a placental origin and is not specific to tumours.

Transposable elements (TEs) are genetic elements that have evolved as crucial regulators of human development and cancer, functioning as both genes and regulatory elements. When TEs become dysregulated in cancer cells, they can serve as alternate promoters to activate oncogenes, a process known as onco-exaptation. This study aimed to explore the expression and epigenetic regulation of onco-exaptation events in early human developmental tissues. We discovered co-expression of some TEs and oncogenes in human embryonic stem cells and first trimester and term placental tissues. Previous studies identified onco-exaptation events in various cancer types, including an AluJb SINE element-LIN28B interaction in lung cancer cells, and showed that the TE-derived LIN28B transcript is associated with poor patient prognosis in hepatocellular carcinoma. This study further characterized the AluJb-LIN28B transcript and confirmed that its expression is restricted to the placenta. Targeted DNA methylation analysis revealed differential methylation of the two LIN28B promoters between placenta and healthy somatic tissues, indicating that some TE-oncogene interactions are not cancer-specific but arise from the epigenetic reactivation of developmental TE-derived regulatory events. In conclusion, our findings provide evidence that some TE-oncogene interactions are not limited to cancer and may originate from the epigenetic reactivation of TE-derived regulatory events that are involved in early development. These insights broaden our understanding of the role of TEs in gene regulation and suggest the potential importance of targeting TEs in cancer therapy beyond their conventional use as cancer-specific markers.

Human placental vascular and perivascular cell heterogeneity differs between first trimester and term, and in pregnancies affected by foetal growth restriction.

Growth-restricted placentae have a reduced vascular network, impairing exchange of nutrients and oxygen. However, little is known about the differentiation events and cell types that underpin normal/abnormal placental vascular formation and function. Here, we used 23-colour flow cytometry to characterize placental vascular/perivascular populations between first trimester and term, and in foetal growth restriction (FGR). First-trimester endothelial cells had an immature phenotype (CD144+/lowCD36-CD146low), while term endothelial cells expressed mature endothelial markers (CD36+CD146+). At term, a distinct population of CD31low endothelial cells co-expressed mesenchymal markers (CD90, CD26), indicating a capacity for endothelial to mesenchymal transition (EndMT). In FGR, compared with normal pregnancies, endothelial cells constituted 3-fold fewer villous core cells (P < 0.05), contributing to an increased perivascular: endothelial cell ratio (2.6-fold, P < 0.05). This suggests that abnormal EndMT may play a role in FGR. First-trimester endothelial cells underwent EndMT in culture, losing endothelial (CD31, CD34, CD144) and gaining mesenchymal (CD90, CD26) marker expression. Together this highlights how differences in villous core cell heterogeneity and phenotype may contribute to FGR pathophysiology across gestation.

Modelling human placental villous development: designing cultures that reflect anatomy.

The use of in vitro tools to study trophoblast differentiation and function is essential to improve understanding of normal and abnormal placental development. The relative accessibility of human placentae enables the use of primary trophoblasts and placental explants in a range of in vitro systems. Recent advances in stem cell models, three-dimensional organoid cultures, and organ-on-a-chip systems have further shed light on the complex microenvironment and cell-cell crosstalk involved in placental development. However, understanding each model's strengths and limitations, and which in vivo aspects of human placentation in vitro data acquired does, or does not, accurately reflect, is key to interpret findings appropriately. To help researchers use and design anatomically accurate culture models, this review both outlines our current understanding of placental development, and critically considers the range of established and emerging culture models used to study this, with a focus on those derived from primary tissue.

Pregnancy-specific uterine vascular reactivity: a data-driven computational model of shear-dependent, myogenic, and mechanical radial artery features.

`The entire maternal circulation adapts to pregnancy, and this adaption is particularly extensive in the uterine circulation where the major vessels double in size to facilitate an approximately 15-fold increase in blood supply to this organ over the course of pregnancy. Several factors may play a role in both the remodeling and biomechanical function of the uterine vasculature including the paracrine microenvironment, passive properties of the vessel wall, and active components of vascular function (incorporating the myogenic response and response to shear stress induced by intravascular blood flow). However, the interplay between these factors and how this plays out in an organ-specific manner to induce the extent of remodeling observed in the uterus is not well understood. Here we present an integrated assessment of the uterine radial arteries, likely rate limiters to the flow of oxygenated maternal blood to the placental surface, via computational modeling and pressure myography. We show that uterine radial arteries behave differently to other systemic vessels (higher compliance and shear-mediated constriction) and that their properties change with the adaptation to pregnancy (higher myogenic tone, higher compliance, and ability to tolerate higher flow rates before constricting). Together, this provides a useful tool to improve our understanding of the role of uterine vascular adaptation in normal and abnormal pregnancies and highlights the need for vascular bed-specific investigations of vascular function in health and disease.NEW & NOTEWORTHY To our knowledge, this is the first data-driven computational model of autoregulation of uterine radial arteries, likely rate limiters of maternal blood flow to the placenta. The study demonstrates that uterine radial arteries behave differently from systemic vessels (higher compliance, shear-mediated constriction) and change in pregnancy (higher myogenic tone, higher compliance, tolerance of higher flow rates). This pregnancy-specific mathematical model of vascular reactivity allows interrogation of the functional significance of incomplete vascular adaption in pathology.

Something old, something new: digital quantification of uterine vascular remodelling and trophoblast plugging in historical collections provides new insight into adaptation of the utero-placental circulation.

STUDY QUESTION: What is the physiological extent of vascular remodelling in and trophoblast plugging of the uterine circulation across the first half of pregnancy? SUMMARY ANSWER: All levels of the uterine vascular tree (arcuate, radial and spiral arteries (SAs)) dilate ∼2.6- to 4.3-fold between 6 and 20 weeks of gestation, with significant aggregates of trophoblasts persisting in the decidual and myometrial parts of SAs beyond the first trimester. WHAT IS KNOWN ALREADY: In early pregnancy, endovascular trophoblasts form 'plugs' in the SAs, transiently inhibiting blood flow to the placenta, whilst concurrently the uterine vasculature undergoes significant adaption to facilitate increased blood delivery to the placenta later in gestation. These processes are impaired in pregnancy disorders, but quantitative understanding of the anatomical changes even in normal pregnancy is poor. STUDY DESIGN, SIZE, DURATION: Serial sections of normal placentae in situ (n = 22) of 6.1-20.5 weeks of gestation from the Boyd collection and Dixon collection (University of Cambridge, UK) were digitalized using a slide scanner or Axio Imager.A1 microscope. PARTICIPANTS/MATERIALS, SETTING, METHODS: Spiral (n = 45), radial (n = 40) and arcuate (n = 39) arteries were manually segmented. Using custom-written scripts for Matlab® software, artery dimensions (Feret diameters; major axes; luminal/wall area) and endovascular trophoblast plug/aggregate (n = 24) porosities were calculated. Diameters of junctional zone SAs within the myometrium (n = 35) were acquired separately using a micrometre and light microscope. Decidual thickness and trophoblast plug depth was measured using ImageJ. MAIN RESULTS AND THE ROLE OF CHANCE: By all measures, radial and arcuate artery dimensions progressively increased from 6.1 to 20.5 weeks (P < 0.01). The greatest increase in SA calibre occurred after 12 weeks of gestation. Trophoblast aggregates were found to persist within decidual and myometrial parts of SA lumens beyond the first trimester, and up to 18.5 weeks of gestation, although those present in the second trimester did not appear to prevent the passage of red blood cells to the intervillous space. Trophoblasts forming these aggregates became more compact (decreased in porosity) over gestation, whilst channel size between cells increased (P = 0.01). Decidual thickness decreased linearly over gestation (P = 0.0003), meaning plugs occupied an increasing proportion of the decidua (P = 0.02). LARGE SCALE DATA: N/A. LIMITATIONS, REASONS FOR CAUTION: Although serial sections were assessed, two-dimensional images cannot completely reflect the three-dimensional properties and connectivity of vessels and plugs/aggregates. Immersion-fixation of the specimens means that vessel size may be under-estimated. WIDER IMPLICATIONS OF THE FINDINGS: Uterine vascular remodelling and trophoblast plug dispersion is a progressive phenomenon that is not completed by the end of the first trimester. Our quantitative findings support the concept that radial arteries present a major site of resistance until mid-gestation. Their dimensional increase at 10-12 weeks of gestation may explain the rapid increase in blood flow to the placenta observed by others at ∼13 weeks. Measured properties of trophoblast plugs suggest that they will impact on the resistance, shear stress and nature of blood flow within the utero-placental vasculature until mid-gestation. The presence of channels within plugs will likely lead to high velocity flow streams and thus increase shear stress experienced by the trophoblasts forming the aggregates. Quantitative understanding of utero-placental vascular adaptation gained here will improve in silico modelling of utero-placental haemodynamics and provide new insights into pregnancy disorders, such as fetal growth restriction. STUDY FUNDING/COMPETING INTEREST(S): This work was supported by a Royal Society Te Aparangi Marsden Grant [18-UOA-135]. A.R.C. is supported by a Rutherford Discovery Fellowship [14-UOA-019]. The authors have no conflict of interest to declare.

Differences in human placental mesenchymal stromal cells may impair vascular function in FGR.

Placentae from pregnancies with foetal growth restriction (FGR) exhibit poor oxygen and nutrient exchange, in part due to impaired placental vascular development. Placental mesenchymal stromal cells (pMSCs) reside in a perivascular niche, where they may influence blood vessel formation/function. However, the role of pMSCs in vascular dysfunction in FGR is unclear. To elucidate the mechanisms by which pMSCs may impact placental vascularisation we compared the transcriptomes of human pMSCs isolated from FGR (<5th centile) (n = 7) and gestation-matched control placentae (n = 9) using Affymetrix microarrays. At the transcriptome level, there were no statistically significant differences between normal and FGR pMSCs; however, several genes linked to vascular function exhibited notable fold changes, and thus the dataset was used as a hypothesis-generating tool for possible dysfunction in FGR. Genes/proteins of interest were followed up by real-time PCR, western blot and immunohistochemistry. Gene expression of ADAMTS1 and FBLN2 (fibulin-2) were significantly upregulated, whilst HAS2 (hyaluronan synthase-2) was significantly downregulated, in pMSCs from FGR placentae (n = 8) relative to controls (n = 7, P < 0.05 for all). At the protein level, significant differences in the level of fibulin-2 and hyaluronan synthase-2, but not ADAMTS1, were confirmed between pMSCs from FGR and control pregnancies by Western blot. All three proteins demonstrated perivascular expression in third-trimester placentae. Fibulin-2 maintains vessel elasticity, and its increased expression in FGR pMSCs could help explain the increased distensibility of FGR blood vessels. ADAMTS1 and hyaluronan synthase-2 regulate angiogenesis, and their differential expression by FGR pMSCs may contribute to the impaired angiogenesis in these placentae.

Structure-function relationships in the feto-placental circulation from in silico interpretation of micro-CT vascular structures.

A well-functioning placenta is critical for healthy fetal development, as the placenta brings fetal blood in close contact with nutrient rich maternal blood, enabling exchange of nutrients and waste between mother and fetus. The feto-placental circulation forms a complex branching structure, providing blood to fetal capillaries, which must receive sufficient blood flow to ensure effective exchange, but at a low enough pressure to prevent damage to placental circulatory structures. The branching structure of the feto-placental circulation is known to be altered in complications such as fetal growth restriction, and the presence of regions of vascular dysfunction (such as hypovascularity or thrombosis) are proposed to elevate risk of placental pathology. Here we present a methodology to combine micro-computed tomography and computational model-based analysis of the branching structure of the feto-placental circulation in ex vivo placentae from normal term pregnancies. We analyse how vascular structure relates to function in this key organ of pregnancy; demonstrating that there is a 'resilience' to placental vascular structure-function relationships. We find that placentae with variable chorionic vascular structures, both with and without a Hyrtl's anastomosis between the umbilical arteries, and those with multiple regions of poorly vascularised tissue are able to function with a normal vascular resistance. Our models also predict that by progressively introducing local heterogeneity in placental vascular structure, large increases in feto-placental vascular resistances are induced. This suggests that localised heterogeneities in placental structure could potentially provide an indicator of increased risk of placental dysfunction.

Reconciling the distinct roles of angiogenic/anti-angiogenic factors in the placenta and maternal circulation of normal and pathological pregnancies.

A branched vascular network is crucial to placental development and is dependent on factors such as vascular endothelial growth factor (VEGF), placental growth factor (PlGF), angiopoietin-1 (Ang-1), angiopoietin-2 (Ang-2), soluble fms-like tyrosine kinase-1 (sFlt-1) and soluble endoglin (sEng) to regulate blood vessel growth. Imbalances in these factors can lead to aberrant placental vascular development. Throughout pregnancy, these factors are also released into the maternal circulation to aid in adapting the maternal cardiovascular system to pregnancy. Increased secretion of anti-angiogenic factors can lead to the development of an anti-angiogenic state in the mother and contribute to the development of pregnancy pathologies such as pre-eclampsia and foetal growth restriction (FGR). Thus, what are commonly referred to as 'angiogenic factors' have distinct functions in the maternal and placental circulations making this a misnomer. Indeed, technical issues in this field such as assay methodology and lack of data considering different placental cell types mean that the physiological roles of these factors in the maternal and placental circulations are frequently muddled in the literature. This review aims to (1) unpick the distinct roles of factors that influence placental vascular development and separate these from the roles of the same factors within the maternal circulation in normal pregnancy and (2) critically assess how imbalances may contribute to the distinct pathophysiological mechanisms underlying pregnancy disorders. Together, this critical assessment of the field endeavours to improve our ability to accurately use these factors as predictive/diagnostic biomarkers in the future.

Feeding Your Baby In Utero: How the Uteroplacental Circulation Impacts Pregnancy.

The utero-placental circulation links the maternal and fetal circulations during pregnancy, ensuring adequate gas and nutrient exchange, and consequently fetal growth. However, our understanding of this circulatory system remains incomplete. Here, we discuss how the utero-placental circulation is established, how it changes dynamically during pregnancy, and how this may impact on pregnancy success, highlighting how we may address knowledge gaps through advances in imaging and computational modeling approaches.

Trophoblast plugs: impact on utero-placental haemodynamics and spiral artery remodelling.

STUDY QUESTION: How does trophoblast plugging impact utero-placental haemodynamics? SUMMARY ANSWER: Physiological trophoblast plug structures are dense enough to restrict flow of oxygenated blood to the intervillous space (IVS) in the first trimester, and result in a shear stress environment upstream of the plugs that promotes spiral artery remodelling. WHAT IS KNOWN ALREADY: Trophoblast plugging of the uterine spiral arteries is thought to be the dominant factor restricting the flow of oxygenated maternal blood to the placenta in the first trimester of pregnancy. However, the extent of plugging, the timing of plug break up, and the impact of plug structure on pregnancy outcomes is debated. STUDY DESIGN, SIZE, DURATION: A computational model of the uterine radial and spiral arteries, incorporating arteriovenous anastomoses was developed. The model was parameterized with our own histological data and previous literature descriptions of the dimensions of the spiral arteries, and the structural properties (porosity) of trophoblast plugs. PARTICIPANTS/MATERIALS, SETTING, METHODS: Structural data were acquired from the literature, and supplemented by images of the spiral arteries acquired by standard thin-section 2D immunohistochemistry, and whole mount immunohistochemistry imaged in 3D by micro-CT. Computational models were solved using Matlab software, via custom written scripts. MAIN RESULTS AND THE ROLE OF CHANCE: We confirm that physiological lengths (>0.1 mm) and porosities (0.2-0.6) of trophoblast plugs are sufficient to restrict the flow of oxygenated maternal blood flow to the placental surface. Trophoblast plugs also have important haemodynamic consequences upstream in the spiral arteries by generating shear stress conditions of <2 dyne/cm2 that promote trophoblast-induced spiral artery remodelling. Structural changes in plugs as they dislodge are likely to result in rapid increases in blood flow to the IVS, and it is likely at this stage of gestation that the major source of resistance in the utero-placental circulation transitions from the spiral arteries to the radial arteries, which then act as a the 'rate-limiting' step to IVS flow. LIMITATIONS, REASONS FOR CAUTION: Structural descriptions of the spiral arteries, radial arteries and trophoblast plugs largely rely on 2D histological sections, or historical measurements. Increased focus on quantitatively assessing the 3D structure of the uterine arteries using more modern imaging technologies in the future will strengthen model predictions. WIDER IMPLICATIONS OF THE FINDINGS: Our work suggests that trophoblast plugs play a previously under-appreciated role in regulating spiral artery remodelling in the first trimester of human pregnancy. This creates the possibility that inadequate trophoblast plugging in the first trimester may contribute to the inadequate artery remodelling observed in pregnancy pathologies such as pre-eclampsia. The incorporation of arteriovenous anastomoses in our model highlights the important influence that shunted blood can play in utero-placental haemodynamics, and together with the emerging role of radial arteries in regulating blood flow to the placenta, the influence of arteriovenous anastomoses on radial artery haemodynamics in normal and pathological pregnancies warrants further investigation. STUDY FUNDING/COMPETING INTEREST(S): This research was supported by a Royal Society of New Zealand Marsden Fund award (13-UOA-032). A.R.C. is supported by a Royal Society of New Zealand Rutherford Discovery Fellowship (14-UOA-019). R.S. was supported by a Gravida (National Centre for Growth and Development) postgraduate scholarship. The authors have no conflicts of interest. TRIAL REGISTRATION NUMBER: N/A.

Placental Nano-vesicles Target to Specific Organs and Modulate Vascular Tone In Vivo.

STUDY QUESTION: How do nano-vesicles extruded from normal first trimester human placentae affect maternal vascular function? SUMMARY ANSWER: Placental nano-vesicles affect the ability of systemic mesenteric arteries to undergo endothelium- and nitric oxide- (NO-) dependent vasodilation in vivo in pregnant mice. WHAT IS KNOWN ALREADY: Dramatic cardiovascular adaptations occur during human pregnancy, including a substantial decrease in total peripheral resistance in the first trimester. The human placenta constantly extrudes extracellular vesicles that can enter the maternal circulation and these vesicles may play an important role in feto-maternal communication. STUDY DESIGN, SIZE, DURATION: Human placental nano-vesicles were administered into CD1 mice via a tail vein and their localization and vascular effects at 30 min and 24 h post-injection were investigated. PARTICIPANTS/MATERIALS, SETTING, METHODS: Nano-vesicles from normal first trimester human placentae were collected and administered into pregnant (D12.5) or non-pregnant female mice. After either 30 min or 24 h of exposure, all major organs were dissected for imaging (n = 7 at each time point) while uterine and mesenteric arteries were dissected for wire myography (n = 6 at each time point). Additional in vitro studies using HMEC-1 endothelial cells were also conducted to investigate the kinetics of interaction between placental nano-vesicles and endothelial cells. MAIN RESULTS AND THE ROLE OF CHANCE: Nano-vesicles from first trimester human placentae localized to the lungs, liver and kidneys 24 h after injection into pregnant mice (n = 7). Exposure of pregnant mice to placental nano-vesicles for 30 min in vivo increased the vasodilatory response of mesenteric arteries to acetylcholine, while exposure for 24 h had the opposite effect (P < 0.05, n = 6). These responses were prevented by L-NAME, an NO synthase inhibitor. Placental nano-vesicles did not affect the function of uterine arteries or mesenteric arteries from non-pregnant mice. Placental nano-vesicles rapidly interacted with endothelial cells via a combination of phagocytosis, endocytosis and cell surface binding in vitro. LARGE SCALE DATA: N/A. LIMITATIONS REASONS FOR CAUTION: As it is not ethical to administer labelled placental nano-vesicles to pregnant women, pregnant CD1 mice were used as a model of pregnancy. WIDER IMPLICATIONS OF THE FINDINGS: This is the first study to report the localization of placental nano-vesicles and their vascular effects in vivo. This work provides new insight into how the dramatic maternal cardiovascular adaptations to pregnancy may occur and indicates that placental extracellular vesicles may be important mediators of feto-maternal communication in a healthy pregnancy. STUDY FUNDING/COMPETING INTEREST(S): This research was supported by the Faculty of Medical and Health Science (FMHS) School of Medicine PBRF research fund to L.W.C. M.T. is a recipient of a University of Auckland Health Research Doctoral Scholarship and the Freemasons Postgraduate Scholarship. No authors have any competing interests to disclose.

In vivo targets of human placental micro-vesicles vary with exposure time and pregnancy.

Throughout human gestation, the placenta extrudes vast quantities of extracellular vesicles (EVs) of different sizes into the maternal circulation. Although multinucleated macro-vesicles are known to become trapped in the maternal lungs and do not enter the peripheral circulation, the maternal organs and cells that smaller placental micro-vesicles interact with in vivo remain unknown. This study aimed to characterise the interaction between placental micro-vesicles and endothelial cells in vitro and to elucidate which organs placental micro-vesicles localise to in vivo Placental macro- and micro-vesicles were isolated from cultured human first trimester placental explants by sequential centrifugation and exposed to human microvascular endothelial cells for up to 72 h. In vivo, placental macro- and micro-vesicles were administered to both non-pregnant and pregnant CD1 mice, and after two or 30 min or 24 h, organs were imaged on an IVIS Kinetic Imager. Placental EVs rapidly interacted with endothelial cells via phagocytic and clathrin-mediated endocytic processes in vitro, with over 60% of maximal interaction being achieved by 30 min of exposure. In vivo, placental macro-vesicles were localised exclusively to the lungs regardless of time of exposure, whereas micro-vesicles were localised to the lungs, liver and kidneys, with different distribution patterns depending on the length of exposure and whether the mouse was pregnant or not. The fact that placental EVs can rapidly interact with endothelial cells and localise to different organs in vivo supports that different size fractions of placental EVs are likely to have different downstream effects on foeto-maternal communication.

Association of Placental Jets and Mega-Jets With Reduced Villous Density.

Spiral arteries (SAs) lie at the interface between the uterus and placenta, and supply nutrients to the placental surface. Maternal blood circulation is separated from the fetal circulation by structures called villous trees. SAs are transformed in early pregnancy from tightly coiled vessels to large high-capacity channels, which is believed to facilitate an increased maternal blood flow throughout pregnancy with minimal increase in velocity, preventing damage to delicate villous trees. Significant maternal blood flow velocities have been theorized in the space surrounding the villi (the intervillous space, IVS), particularly when SA conversion is inadequate, but have only recently been visualized reliably using pulsed wave Doppler ultrasonography. Here, we present a computational model of blood flow from SA openings, allowing prediction of IVS properties based on jet length. We show that jets of flow observed by ultrasound are likely correlated with increased IVS porosity near the SA mouth and propose that observed mega-jets (flow penetrating more than half the placental thickness) are only possible when SAs open to regions of the placenta with very sparse villous structures. We postulate that IVS tissue density must decrease at the SA mouth through gestation, supporting the hypothesis that blood flow from SAs influences villous tree development.

Proteomic characterization of macro-, micro- and nano-extracellular vesicles derived from the same first trimester placenta: relevance for feto-maternal communication.

STUDY QUESTION: What proteins are carried by extracellular vesicles (EVs) released from normal first trimester placentae? SUMMARY ANSWER: One thousand five hundred and eighty-five, 1656 and 1476 proteins were characterized in macro-, micro- and nano-vesicles, respectively, from first trimester placentae, with all EV fractions being enriched for proteins involved in vesicle transport and inflammation. WHAT IS KNOWN ALREADY: Placental EVs are being increasingly recognized as important mediators of both healthy and pathological pregnancies. However, current research has focused on detecting changes in specific proteins in particular fractions of vesicles during disease. This is the first study to investigate the full proteome of different-sized fractions of EVs from the same first trimester placenta and highlights the differences/similarities between the vesicle fractions. STUDY DESIGN, SIZE, DURATION: A well-established ex vivo placental explant culture model was used to generate macro-, micro- and nano-vesicles from 56 first trimester placentae. Vesicle fractions were collected by differential ultracentrifugation, quantified and characterized. PARTICIPANTS/MATERIALS, SETTING, METHODS: Placental macro-, micro- and nano-vesicles were characterized by microscopy, dynamic light scattering and nanoparticle tracking analysis. The proteome of each EV fraction was interrogated using liquid chromatography-coupled tandem mass spectrometry. Results were validated by semi-quantitative western blotting. MAIN RESULTS AND THE ROLE OF CHANCE: A total of 1585, 1656 and 1476 proteins were identified in macro-, micro- and nano-vesicles, respectively. One thousand one hundred and twenty-five proteins were shared between all three fractions while up to 223 proteins were unique to each fraction. Gene Ontology pathway analysis showed an enrichment of proteins involved in vesicle transport and inflammation in all three fractions of EVs. The expression levels of proteins involved in internalization of vesicles (annexin V, calreticulin, CD31, CD47), the complement pathway [C3, decay-accelerating factor (DAF), membrane cofactor protein (MCP), protectin] and minor histocompatibility antigens [ATP-dependent RNA helicase (DDX3), ribosomal protein S4 (RPS4)] were different between different-sized EVs. LIMITATIONS, REASONS FOR CAUTION: This study is largely hypothesis-generating in nature. It is important to validate these findings using EVs isolated from maternal plasma and the function of the different EV fractions would need further investigation. WIDER IMPLICATIONS OF THE FINDINGS: Our results support the concept that various EV factions can interact with different maternal cells and have unique effects to mediate feto-maternal communication during early pregnancy. This study also provides a list of candidate proteins, which may inform the identification of robust markers that can be used to isolate placental vesicles from the maternal blood in the future. STUDY FUNDING/COMPETING INTERESTS: M.T. is a recipient of the University of Auckland Health Research Doctoral Scholarship and the Freemasons Postgraduate Scholarship. This project was supported by a School of Medicine Performance-based research fund (PBRF) grant awarded to L.W.C. No authors have any conflicts of interest to disclose.

A multiscale model of placental oxygen exchange: The effect of villous tree structure on exchange efficiency.

The placenta is critical to fetal health during pregnancy as it supplies oxygen and nutrients to maintain life. It has a complex structure, and alterations to this structure across spatial scales are associated with several pregnancy complications, including intrauterine growth restriction (IUGR). The relationship between placental structure and its efficiency as an oxygen exchanger is not well understood in normal or pathological pregnancies. Here we present a computational framework that predicts oxygen transport in the placenta which accounts for blood and oxygen transport in the space around a placental functional unit (the villous tree). The model includes the well-defined branching structure of the largest villous tree branches, as well as a smoothed representation of the small terminal villi that comprise the placenta's gas exchange interfaces. The model demonstrates that oxygen exchange is sensitive to villous tree geometry, including the villous branch length and volume, which are seen to change in IUGR. This is because, to be an efficient exchanger, the architecture of the villous tree must provide a balance between maximising the surface area available for exchange, and the opposing condition of allowing sufficient maternal blood flow to penetrate into the space surrounding the tree. The model also predicts an optimum oxygen exchange when the branch angle is 24 °, as villous branches and TBs are spread out sufficiently to channel maternal blood flow deep into the placental tissue for oxygen exchange without being shunted directly into the DVs. Without concurrent change in the branch length and angles, the model predicts that the number of branching generations has a small influence on oxygen exchange. The modelling framework is presented in 2D for simplicity but is extendible to 3D or to incorporate the high-resolution imaging data that is currently evolving to better quantify placental structure.

Applying Scientific Rationale to the Current Perceptions and Explanations of Massage and Miscarriage in the First Trimester.

Miscarriage is a relatively common occurrence, impacting 8-15% of clinically recognised pregnancies, and up to 30% of all conceptions. The public perception of the risk factors associated with miscarriage does not match the evidence. Evidence indicates that there are very few modifiable factors to prevent miscarriage, and the majority of the time little could have been done to prevent a spontaneous miscarriage. However, the public perception is that consuming drugs, lifting a heavy object, previous use of an intrauterine device, or massage can all contribute to miscarriage. While misinformation about the causes and risk factors of miscarriage continues to circulate, pregnant women will experience confusion about what activities they can (and cannot) do in early pregnancy, including receiving a massage. Pregnancy massage is an important component of massage therapy education. The resources that underpin pregnancy massage coursework consist of educational print content that includes direction and caution that massage in the first trimester, if done 'incorrectly' or in the 'wrong' location, can contribute to adverse outcomes such as miscarriage. The most common statements, perceptions and explanations for massage and miscarriage cover three broad areas: 1) maternal changes from massage affects the embryo/fetus; 2) massage leads to damage of the fetus/placenta; and 3) aspects of the massage treatment in the first trimester initiate contractions. The goal of this paper is to use scientific rationale to critically consider the validity of the current perceptions and explanations of massage therapy and miscarriage. Whilst direct evidence from clinical trials was lacking, considerations of physiological mechanisms regulating pregnancy and known risk factors associated with miscarriage provide no evidence that massage in pregnancy would increase a patient's risk of miscarriage. This scientific rationale should be addressed when teaching pregnancy massage courses.

Multi-scale Modelling of Shear Stress on the Syncytiotrophoblast: Could Maternal Blood Flow Impact Placental Function Across Gestation?

The placenta is a critical fetal exchange organ, with a complex branching tree-like structure. Its surface is covered by a single multinucleated cell, the syncytiotrophoblast, which bathes in maternal blood for most of pregnancy. Mechanosensing protein expression by the syncytiotrophoblast at term suggests that shear stress exerted by maternal blood flow may modulate placental development and function. However, it is not known how the mechanosensitive capacity of the syncytiotrophoblast, or the shear stress it experiences, change across gestation. Here, we show that the syncytiotrophoblast expresses both mechanosensitive ion channels (Piezo 1, Polycystin 2, TRPV6) and motor proteins associated with primary cilia (Dynein 1, IFT88, Kinesin 2), with higher staining for all these proteins seen in late first trimester placentae than at term. MicroCT imaging of placental tissue was then used to inform computational models of blood flow at the placentone scale (using a porous media model), and at the villous scale (using explicit flow simulations). These two models are then linked to produce a combined model that allows the variation of shear stress across both these scales simultaneously. This combined model predicts that the range of shear stress on the syncytiotrophoblast is higher in the first-trimester than at term (0.8 dyne/cm2 median stress compared to 0.04 dyne/cm2) when considering both these scales. Together, this suggests that the nature of blood flow through the intervillous space, and the resulting shear stress on the syncytiotrophoblast have important influences on placental morphogenesis and function from early in pregnancy.

Know the game: Insights to help early career researchers successfully navigate academia.

Career trajectories in science are often unpredictable, with many early and mid-career researchers working multiple successive fixed-term contracts, and physically relocating to take up employment opportunities. Whilst this can provide exciting opportunities to change research direction, acquire new skills, and see the world, the precarity of this scenario is also a significant cause of anxiety for many, and can have a negative impact on their ability to maintain career momentum and trajectory, access institutional financial benefits, or make long term career or financial plans. Here, we build on a pair of workshops held at the 2021 International Federation of Placenta Associations annual conference to discuss two key areas important to help early career researchers navigate their careers - building an academic profile, and the financial ramifications of academic careers.

From stem cells to spiral arteries: A journey through early placental development.

Early placental development lays the foundation of a healthy pregnancy, and numerous tightly regulated processes must occur for the placenta to meet the increasing nutrient and oxygen exchange requirements of the growing fetus later in gestation. Inadequacies in early placental development can result in disorders such as fetal growth restriction that do not present clinically until the second half of gestation. Indeed, growth restricted placentae exhibit impaired placental development and function, including reduced overall placental size, decreased branching of villi and the blood vessels within them, altered trophoblast function, and impaired uterine vascular remodelling, which together combine to reduce placental exchange capacity. This review explores the importance of early placental development across multiple anatomical aspects of placentation, from the stem cells and lineage hierarchies from which villous core cells and trophoblasts arise, through extravillous trophoblast invasion and spiral artery remodelling, and finally remodelling of the larger uterine vessels.

Full spectrum flow cytometry reveals mesenchymal heterogeneity in first trimester placentae and phenotypic convergence in culture, providing insight into the origins of placental mesenchymal stromal cells.

Single-cell technologies (RNA-sequencing, flow cytometry) are critical tools to reveal how cell heterogeneity impacts developmental pathways. The placenta is a fetal exchange organ, containing a heterogeneous mix of mesenchymal cells (fibroblasts, myofibroblasts, perivascular, and progenitor cells). Placental mesenchymal stromal cells (pMSC) are also routinely isolated, for therapeutic and research purposes. However, our understanding of the diverse phenotypes of placental mesenchymal lineages, and their relationships remain unclear. We designed a 23-colour flow cytometry panel to assess mesenchymal heterogeneity in first-trimester human placentae. Four distinct mesenchymal subsets were identified; CD73+CD90+ mesenchymal cells, CD146+CD271+ perivascular cells, podoplanin+CD36+ stromal cells, and CD26+CD90+ myofibroblasts. CD73+CD90+ and podoplanin + CD36+ cells expressed markers consistent with cultured pMSCs, and were explored further. Despite their distinct ex-vivo phenotype, in culture CD73+CD90+ cells and podoplanin+CD36+ cells underwent phenotypic convergence, losing CD271 or CD36 expression respectively, and homogenously exhibiting a basic MSC phenotype (CD73+CD90+CD31-CD144-CD45-). However, some markers (CD26, CD146) were not impacted, or differentially impacted by culture in different populations. Comparisons of cultured phenotypes to pMSCs further suggested cultured pMSCs originate from podoplanin+CD36+ cells. This highlights the importance of detailed cell phenotyping to optimise therapeutic capacity, and ensure use of relevant cells in functional assays.