Molecular cloning and early expression of chick embryo SCO-spondin

SCO-spondin is a multidomain glycoprotein secreted by the subcommissural organ (SCO). It belongs to the thrombospondin type 1 repeat superfamily and has been identified in several vertebrate species. We report the cloning of the chick SCO-spondin ortholog and examine its temporal and spatial expression during early embryogenesis from Hamburger and Hamilton (HH) stage 12 to HH stage 21. Chick SCO-spondin cDNA contains a long open reading frame encoding a predicted protein of 5255 amino acids. Northern blot analysis has revealed SCO-spondin mRNA as a band of about 15 kb. Many conserved domains have been identified, including 27 thrombospondin type 1 repeats, 13 low-density lipoprotein receptor type A domains, one EMI domain (a cysteine-rich domain of extracellular proteins), three von Willebrand factor type D domains, and one cystine knot C-terminal domain. Whole-mount in situ hybridization enabled the first signal of mRNA expression to be detected at HH stage 17, exclusively in a thin area of the prosencephalon roof plate. During the following stages of development, SCO-spondin expression remained restricted to this region. The multidomain structure of SCO-spondin and its early expression suggest that it plays a role in developmental processes in the central nervous system.     

Molecular heterogeneity of creatine kinase isoenzymes

The [32P]phosphoamino acids in proteins of first trimester and term-cultured human placentas have been separated and their relative amounts were measured. A significant phosphorylation of tyrosine residues could be detected in the cultured placental tissue at different stages of gestation. The phosphotyrosine accounts for 2-4% of the total acid-stable phosphate in the phosphoamino acids after partial acid hydrolysis. The difference in the extent of [32P]tyrosine in various placentas seems to be a function of biological variation of the individual placentas, rather than a function of placental age and stage of gestation. In contrast, a significant difference in the phosphorylation ratio of serine and threonine could be measured between first trimester and term placentas. As more evidence is accumulating that protein phosphorylation of tyrosine is involved in the processes of cellular growth and proliferation, our findings of the relatively high tyrosine phosphorylation in human placenta strongly suggest that this type of protein phosphorylation may play an important role in the placental growth and development. Furthermore, these findings may correlate with the existence of the endogenous RNA virus-like particles found in normal human placenta.     

Extracellular nucleic acids in maternal circulation as potential biomarkers for placental insufficiency

Since the placenta is being continuously remodeled during normal placental development, extracellular nucleic acids of both fetal and placental origin, packed into either trophoblast-derived apoptotic bodies or shedding syncytiotrophoblast microparticles, may be detected in maternal circulation during the course of normal gestation. Placental-insufficiency-related pregnancy complications have been shown to be associated with excessive placental trophoblast apoptosis and shedding of placenta debris. Recent advances in the field are reviewed with a focus on the diagnostic potential of particular molecular biomarkers and their eventual implementation in the currently used predictive and diagnostic algorithms for placental-insufficiency-related pregnancy complications.     

Phosphorylation of tyrosine in cultured human placenta

The [³²P]phosphoamino acids in proteins of first trimester and term-cultured human placentas have been separated and their relative amounts were measured. A significant phosphorylation of tyrosine residues could be detected in the cultured placental tissue at different stages of gestation. The phosphotyrosine accounts for 2–4% of the total acid-stable phosphate in the phosphoamino acids after partial acid hydrolysis. The difference in the extent of [³²P]tyrosine in various placentas seems to be a function of biological variation of the individual placentas, rather than a function of placental age and stage of gestation. In contrast, a significant difference in the phosphorylation ratio of serine and threonine could be measured between first trimester and term placentas. As more evidence is accumulating that protein phosphorylation of tyrosine is involved in the processes of cellular growth and proliferation, our findings of the relatively high tyrosine phosphorylation in human placenta strongly suggest that this type of protein phosphorylation may play an important role in the placental growth and development. Furthermore, these findings may correlate with the existence of the endogenous RNA virus-like particles found in normal human placenta.     

Phosphorylation of tyrosine in cultured human placenta

The [³²P]phosphoamino acids in proteins of first-trimester and term-cultured human placentas have been separated and their relative amounts have been measured. Significant phosphorylation of tyrosine residues could be detected in the cultured placental tissue at different stages of gestation. The phosphotyrosine accounts for 2–4% of the total acid-stable phosphate in the phosphoamino acids after partial acid hydrolysis. The difference in the extent of [³²P]tyrosine in various placentas seems to be a function of biological variation of the individual placentas, rather than a function of placental age and stage of gestation. In contrast, a significant difference in the phosphorylation ratio of serine and threonine could be measured between first-trimester and term placentas. As more evidence is accumulating that protein phosphorylation of tyrosine is involved in the processes of cellular growth and proliferation, our findings of the relatively high tyrosine phosphorylation in human placenta strongly suggest that this type of protein phosphorylation may play an important role in the placental growth and development. Furthermore, these findings may correlate with the existence of the endogenous RNA virus-like particles found in normal human placenta.     

Cloning of the bovine antiapoptotic regulator, BCL2-related protein A1, and its expression in trophoblastic binucleate cells of bovine placenta

This report studied the identification and sequence of a full-length cDNA for the bovine BCL2 antiapoptotic family member, BCL2-related protein A1 (BCL2A1), and its localized and quantitative expression in the placenta to clarify the regulatory mechanism of trophoblast cell proliferation and differentiation during implantation and placental development. We cloned a full-length bovine BCL2A1 cDNA with 725 nucleotides and an open-reading frame corresponding to a protein of 175 amino acids. The predicted amino acid sequence shared 78% homology with human BCL2A1. All BCL2 homology domains (BH1, BH2, BH3, and BH4) in bovine BCL2A1 were conserved as well as in other mammalian BCL2A1. In the placentomes, in situ hybridization demonstrated that the BCL2A1 was limited in binucleate cells expressing various pregnancy-specific molecules like placental lactogen. BCL2-associated X protein (BAX) was also expressed in binucleate cells. Quantitative real-time RT-PCR detection exhibited a high-level expression of BCL2A1 in the conceptus at Day 21 of gestation, and it was expressed and increased in the extraembryonic membrane, cotyledon, and intercotyledon from implantation to term. BAX expression intensity increased with progression of gestation and remained elevated in postpartum. Caspase-3 protein (CASP3) and mRNA (CASP3) were detected from late gestation to postpartum in placenta as well as in the results of TUNEL detection. We believe that the apoptosis of binucleate cells may be regulated by the balance of the BCL2A1 and BAX. BCL2A1 genes produced a BCL2A1 protein in the mammalian cell-expression system. This molecule is a new candidate for antiapoptotic maintenance of the binucleate cells that support placental functions throughout gestation in bovine.     

The serine protease HtrA1 is upregulated in the human placenta during pregnancy.

The placenta has a dynamic and continuous capacity for self-renewal. The molecular mechanisms responsible for controlling trophoblast proliferation are still unclear. It is generally accepted that the simultaneous activity of proteins involved in cell proliferation, apoptosis, and extracellular matrix degradation plays an important role in correct placental development. We investigated in depth the expression of the serine protease HtrA1 during pregnancy in human placenta by in situ hybridization and immunohistochemistry, we demonstrated that HtrA1 displayed a low level of expression in the first trimester of gestation and a strong increase of HtrA1 expression in the third trimester. Finally, by electron microscopy, we demonstrated that HtrA1 was localized either in the cytoplasm of placental cells, especially close to microvilli that characterized the plasma membrane of syncytiotrophoblast cells, or in the extracytoplasmic space of the stroma of placental villi, particularly in the spaces between collagen fibers and on collagen fibers themselves. The expression pattern of HtrA1 in human placentas strongly suggests a role for this protein in placental development and function. Moreover, on the basis of its subcellular distribution it can be postulated that HtrA1 acts on different targets, such as intracellular growth factors or extracellular matrix proteins, to favor the correct formation/function of the placenta.     

Copy Number Variation Is a Fundamental Aspect of the Placental Genome

Discovery of lineage-specific somatic copy number variation (CNV) in mammals has led to debate over whether CNVs are mutations that propagate disease or whether they are a normal, and even essential, aspect of cell biology. We show that 1,000N polyploid trophoblast giant cells (TGCs) of the mouse placenta contain 47 regions, totaling 138 Megabases, where genomic copies are underrepresented (UR). UR domains originate from a subset of late-replicating heterochromatic regions containing gene deserts and genes involved in cell adhesion and neurogenesis. While lineage-specific CNVs have been identified in mammalian cells, classically in the immune system where V(D)J recombination occurs, we demonstrate that CNVs form during gestation in the placenta by an underreplication mechanism, not by recombination nor deletion. Our results reveal that large scale CNVs are a normal feature of the mammalian placental genome, which are regulated systematically during embryogenesis and are propagated by a mechanism of underreplication.     

Vitamin D-dependent calcium-binding protein. Immunochemical studies and synthesis by placental tissue in vitro

A protein similar to rat intestinal calcium-binding protein (CaBP) has been identified in both mouse placenta and mouse small intestine. The mouse protein had a molecular weight of approximately 10,000, exhibited cation-binding properties, and demonstrated immunologic identity with vitamin D-dependent rat CaBP. Under normal dietary conditions, the concentrations of CaBP in mouse placenta and intestine increased 6- and 3-fold, respectively, during the third trimester of pregnancy in parallel with the fetal demands for skeletal mineral. Studies of in vitro protein synthesis indicated that CaBP was synthesized by placental tissue. Slices of mouse or rat placental tissue (12-18-day gestation) were incubated with [3H]leucine and the biosynthesis of placental CaBP was quantified by an immunoprecipitation method using rabbit antiserum to rat intestinal CaBP. Sodium dodecyl sulfate gel electrophoresis of the radioactive immune complex revealed a single 3H-labeled peak corresponding to the molecular weight of rat and mouse CaBP (10,050). The amount of CaBP synthesized by mouse placental tissue was dependent upon gestational age of the placenta and reflected the in vivo changes in placental CaBP content observed during gestation. These data indicate that CaBP is synthesized by placenta and provide an in vitro model for studying the developmental control of placental CaBP synthesis.     

Mek1 and Mek2 functions in the formation of the blood placental barrier

The ERK/MAPK signaling pathway is involved in several cellular functions. Inactivation in mice of genes encoding members of this pathway is often associated with embryonic death resulting from abnormal placental development. The placenta is essential for nutritional and gaseous exchanges between maternal and embryonic circulations, as well as for the removal of metabolic wastes. These exchanges take place without direct contact between the two circulations. In mice, the hematoplacental barrier consists in a triple layer of trophoblast cells and endothelial cells of the embryo. MEK1 and MEK2 are double specificity serine-threonine/tyrosine kinases responsible for the activation of ERK1 and ERK2. Mek1 inactivation results in placental anomalies due to trophoblast cell proliferation and differentiation defects leading to severe delays in the development of placenta and causing the death of the embryo. Although Mek2(-/-) mutant mice survived without any apparent phenotype, double heterozygous Mek1(+/-)Mek2(+/-) mutants die during gestation from placental malformations. Together, these data emphasize the crucial role of the ERK/MAPK cascade in the formation of extraembryonic structures.     

Maternal stress alters endocrine function of the feto-placental unit in rats

Prenatal stress (PS) can cause early and long-term developmental effects resulting in part from altered maternal and/or fetal glucocorticoid exposure. The aim of the present study was to assess the impact of chronic restraint stress during late gestation on feto-placental unit physiology and function in embryonic (E) day 21 male rat fetuses. Chronic stress decreased body weight gain and food intake of the dams and increased their adrenal weight. In the placenta of PS rats, the expression of glucose transporter type 1 (GLUT1) was decreased, whereas GLUT3 and GLUT4 were slightly increased. Moreover, placental expression and activity of the glucocorticoid "barrier" enzyme 11beta-hydroxysteroid dehydrogenase type 2 was strongly reduced. At E21, PS fetuses exhibited decreased body, adrenal pancreas, and testis weights. These alterations were associated with reduced pancreatic beta-cell mass, plasma levels of glucose, growth hormone, and ACTH, whereas corticosterone, insulin, IGF-1, and CBG levels were unaffected. These data emphasize the impact of PS on both fetal growth and endocrine function as well as on placental physiology, suggesting that PS could program processes implied in adult biology and pathophysiology.     

Developmental changes in the intraplacental distribution of placental lactogen and alkaline phosphatase in the rat

The junctional and labyrinth regions of the rat chorioallantoic placenta during the second half of gestation showed different patterns of development with regard to DNA, protein, placental lactogen and alkaline phosphatase content. DNA and protein measurements indicated that growth of the labyrinth region was more rapid and persisted for longer during gestation than did growth in the junctional zone. At midpregnancy the junctional zone was the main source of placental lactogen whereas by late pregnancy both regions contributed considerable amounts. On Day 20 of gestation the labyrinth region contained significantly more placental lactogen than did the junctional zone. Alkaline phosphatase activity was predominant in the labyrinth zone throughout the second half of gestation. The results indicate that the chorioallantoic placenta is composed of two functionally distinct regions.     

Expression of an isoform of the testis-specific estrogen sulfotransferase in the murine placenta during the late gestational period

Cytosolic sulfotransferases play essential roles in regulating the activities and transfer of steroids. To evaluate their biological significance in the murine uterus and placenta during the course of gestation, we determined their activities with several steroids as substrates. Activated estrogen sulfotransferase (EST) was found in the placenta and uterus during the late gestational period. Reverse-transcribed cDNA of murine placental EST (mpEST) was isolated from mouse placenta at 18 days of gestation and its expression in the tissue coincided with a change in its enzyme activity. The open-reading frame of mpEST encodes a protein composed of 296 amino acids with a predicted molecular mass of 35.5 kDa and was revealed to be an isoform of the murine testis-specific EST gene (99.7%). Also, the amino acid sequence of mpEST showed 49.6 and 77.9% homology with human placental and endometrial EST, respectively, showing that it corresponds to human endometrial EST. COS-7 cells transfected with mpEST exhibited sulfotransferase activity with the phenolic hydroxy groups of steroids and artificial substrates. The best acceptor substrate was estrogen.     

Preserved placental oxygenation and development during severe systemic hypoxia

Local tissue oxygenation profoundly influences placental development. To elucidate the impact of hypoxia on cellular and molecular adaptation in vivo, pregnant mice at embryonic days 7.5-11.5 were exposed to reduced environmental oxygen (6-7% O2) for various periods of time. Hypoxia-inducible factor (HIF)-1alpha mRNA was highly expressed in the placenta, whereas HIF-2alpha was predominantly found in the decidua, indicating that HIF-1 is a relevant oxygen-dependent factor involved in placental development. During severe hypoxia, HIF-1alpha protein was strongly induced in the periphery but, however, not in the labyrinth layer of the placenta. Accordingly, no indication for tissue hypoxia in this central area was detected with 2-(2-nitro-1H-imidazol-1-yl)-N-(2,2,3,3,3-pentafluoropropyl)acetamide staining and VEGF expression as hypoxic markers. The absence of significant tissue hypoxia was reflected by preserved placental architecture and trophoblast differentiation. In the search for mechanisms preventing local hypoxia, we found upregulation of endothelial nitric oxide synthase (NOS) expression in the labyrinth layer. Inhibition of NOS activity by N(omega)-nitro-L-arginine methyl ester application resulted in ubiquitous placental tissue hypoxia. Our results show that placental oxygenation is preserved even during severe systemic hypoxia and imply that NOS-mediated mechanisms are involved to protect the placenta from maternal hypoxia.     

胎盘发生中的表观遗传学

胚外组织尤其是胎盘的正常发生对于维持哺乳动物胎儿在子宫中的发育和生长是必须的。胎盘发生是一个复杂的基因表达调控的过程,近年来的研究表明表观遗传在该过程中也起着重要作用。表观遗传调控在胎盘发生过程的几个主要事件中发挥作用,包括表观遗传对滋养层细胞分化和发育的调控、印记基因对胎盘发生和营养转运的调控、胎盘中的X染色体失活,以及胎盘表观遗传调控异常所导致的妊娠相关疾病。     

Expression of the retinoblastoma-related p107 and Rb2/p130 genes in human placenta: an immunohistochemical study

It has been proposed that tumor suppressor genes may have a role in the mechanisms of proliferation and differentiation during human placental development. The Retinoblastoma gene family is a well known family of tumor suppressor genes. Many studies have pointed out a role of this family not only in cell cycle progression, but also during development and differentiation. On the light of these observations we have investigated the immunohistochemical expression pattern of the Retinoblastoma family members, p107 and Rb2/p130 in human placenta samples in first trimester and full-term placental sections. p107 and pRb2/p130 showed the most abundant expression levels during the first trimester of gestation and progressively declined to being barely detectable in the placenta by late gestation. These results indicate that the expression of the above genes is modulated during placental development and suggest a mechanism for controlling trophoblast proliferation.     

The marsupial placenta: a phylogenetic analysis

The structure, physiology, and endocrinology of the yolk sac placenta of different marsupial groups is compared and phylogenetically analyzed to provide information on placental characters in the marsupial stem species. We conclude that the marsupial stem species possessed a functional yolk sac placenta. Histotrophic nutrition by uterine secretion decreased during late pregnancy and at least half of the yolk sac was vascularized at the time of shell coat rupture. Due to yolk sac fusion, the larger part of the avascular, bilaminar yolk sac could not serve as a placenta at late gestation in the polyovular marsupial stem species. The bilaminar yolk sac gained a relatively greater importance for nutrition in monovular australidelphians. In macropodids a greater proportion of the yolk sac remained bilaminar at the time of shell coat rupture than in the stem species. Another derived feature of macropodids is the sustained plasma progesterone synthesis that is in turn responsible for an extended secretory phase of the uterus and a lengthened gestation. The placenta of the marsupial stem species was probably capable of metabolising histo- and hemotrophes. Recognition of pregnancy during early stages of development is a derived character of macropodids that we suggest did not occur in the marsupial stem species. However, birth and birth behaviour were apparently induced by prostaglandins in the marsupial stem species. Although the yolk sac formed the definitive placenta, it is likely that the allantois provided a supplementary placental function in the marsupial stem species, but that the role of the allantois became progressively less important during the evolution of marsupial placentation.     

Evolution of placental proteases

The placenta is a critical organ in mammals required for the transport of nutrients from the mother to the fetus during gestation. Other critical functions of the placenta include hormone regulation and immune regulation. The origin of the mammals and early placenta is relatively recent in evolutionary terms, and consequently there are few placenta-specific genes. In two separate branches of mammalian evolution, gene duplications have given rise to two large families of protease genes that are expressed only by placental tissues. A family of aspartic protease genes is expressed only in artiodactyls, and a family of cysteine protease genes is expressed only in rodents. These genes have probably evolved to perform specific functions in the placenta that are carried out by broader specificity proteases in mammalian species that do not express these proteases.     

Expression of low density lipoprotein receptor gene in human placenta during pregnancy

Mammalian cells require cholesterol as a structural component of plasma membranes. It is also required for placental steroid synthesis. De novo synthesis of cholesterol is limited in human placenta and cholesterol is obtained mainly from plasma low density lipoprotein (LDL). Cholesterol delivery from LDL is mediated by receptor-mediated uptake and the receptor amount is the most important factor for cellular delivery. Thus, the regulation of receptor synthesis is important for placental development and function. Since the regulation of LDL receptor gene expression has not been studied in human placenta, LDL receptor mRNA was measured in placentae of 5-40 weeks of gestation by hybridization of RNA with 32P-labeled cDNA for human LDL receptor. Two mRNA species for LDL receptor were demonstrated by Northern blot analysis. The longer mRNA [5.3 kilobases (kb)] was much more abundant than the shorter mRNA (3.7 kb). The amount of 5.3 kb mRNA was highest early in gestation and decreased during pregnancy. However, the amount of 3.7 kb mRNA did not change appreciably during gestation. Dot blot analysis of 26 placental mRNAs obtained from various stages of gestation revealed a negative correlation between LDL receptor mRNA and gestation (r = -0.76, P less than 0.001). Considering the rapid growth of the trophoblast during gestation, especially in the first and the second trimester, increased expression of the LDL receptor gene and subsequent translation are expected for efficient cholesterol uptake to provide a sufficient substrate for cell growth. Possible mechanisms for the appearance of two mRNA species for LDL receptor are also discussed.