Gayathri Rajaraman

Novel Homeobox Genes are Differentially Expressed in Placental Microvascular Endothelial Cells Compared with Macrovascular Cells

Angiogenesis is fundamental to normal placental development and aberrant angiogenesis contributes substantially to placental pathologies. The complex process of angiogenesis is regulated by transcription factors leading to the formation of endothelial cells that line the microvasculature. Homeobox genes are important transcription factors that regulate vascular development in embryonic and adult tissues. We have recently shown that placental homeobox genes HLX, DLX3, DLX4, MSX2 and GAX are expressed in placental endothelial cells. Hence, the novel homeobox genes TLX1, TLX2, TGIF, HEX, PHOX1, MEIS2, HOXB7, and LIM6 were detected that have not been reported in endothelial cells previously. Importantly, these homeobox genes have not been previously reported in placental endothelial cells and, with the exception of HEX, PHOX1 and HOXB7, have not been described in any other endothelial cell type. Reverse transcriptase PCR was performed on cDNA from freshly isolated placental microvascular endothelial cells (PLEC), and the human placental microvascular endothelial cell line HPEC. cDNAs prepared from control term placentae, human microvascular endothelial cells (HMVEC) and human umbilical vein macrovascular endothelial cells (HUVEC) were used as controls. PCR analyses showed that all novel homeobox genes tested were expressed by all endothelial cells types. Furthermore, real-time PCR analyses revealed that homeobox genes TLX1, TLX2 and PHOX1 relative mRNA expression levels were significantly decreased in HUVEC compared with microvascular endothelial cells, while the relative mRNA expression levels of MEIS2 and TGIF were significantly increased in macrovascular cells compared with microvascular endothelial cells. Thus we have identified novel homeobox genes in microvascular endothelial cells and have shown that homeobox genes are differentially expressed between micro- and macrovascular endothelial cells.

Downstream Targets of Homeobox Gene HLX Show Altered Expression in Human Idiopathic Fetal Growth Restriction

Fetal growth restriction (FGR), a clinically significant pregnancy disorder, is poorly understood at the molecular level. This study investigates idiopathic FGR associated with placental insufficiency. Previously, we showed that the homeobox gene HLX is expressed in placental trophoblast cells and that HLX expression is significantly decreased in human idiopathic FGR. Here, we used the novel approach of identifying downstream targets of HLX in cell culture to detect potentially important genes involved in idiopathic FGR. Downstream targets were revealed by decreasing HLX expression in cultured trophoblast cells with HLX-specific small interfering RNAs to model human idiopathic FGR and comparing these levels with controls using a real-time PCR-based gene profiling system. Changes in candidate HLX target mRNA levels were verified in an independent trophoblast cell line, and candidate target gene expression was assessed in human idiopathic FGR-affected placentae (n = 25) compared with gestation-matched controls (n = 25). The downstream targets RB1 and MYC, cell cycle regulatory genes, showed significantly increased mRNA levels in FGR-affected tissues compared with gestation-matched controls, whereas CCNB1, ELK1, JUN, and CDKN1 showed significantly decreased mRNA levels (n = 25, P < 0.001, t-test). The changes for RB1 and CDKN1C were verified by Western blot analysis in FGR-affected placentae compared with gestation-matched controls (n = 6). We conclude that cell cycle regulatory genes RB1, MYC, CCNB1, ELK1, JUN, and CDKN1C, which control important trophoblast cell functions, are targets of HLX.

Decorin expression is decreased in human idiopathic fetal growth restriction

Fetal growth restriction (FGR) is a clinically significant pregnancy disorder in which the fetus fails to achieve its full growth potential in utero. Most cases of FGR are idiopathic and are associated with placental thrombosis. Previous studies suggest that proteoglycans, such as decorin, that contain the glycosaminoglycan dermatan sulfate are the principal anticoagulants in the normal placenta. The present study investigated decorin expression in placentas from pregnancies complicated by idiopathic FGR (n = 26) and gestation-matched controls (n = 27). Real-time polymerase chain reaction demonstrated significantly reduced decorin mRNA expression in FGR compared with control (1.52 +/- 0.14 v. 2.21 +/- 0.22, respectively; P < 0.01). Immunoblotting revealed decreased decorin protein (40 kDa) expression in FGR compared with controls (420.8 +/- 39.0 v. 690.1 +/- 42.2, respectively; n = 12 in each group; P = 0.0007). Immunohistochemistry demonstrated the presence of immunoreactive decorin protein in the placental villous stroma surrounding the fetal capillaries and a significant decrease in decorin protein presence in FGR compared with control (1.75 +/- 0.66 v. 2.98 +/- 1.12, respectively; n = 6 in each group; P < 0.01, t-test). This is the first study to demonstrate reduced decorin in idiopathic FGR, indicating a potentially significant role for decorin in the aetiology of placental thrombosis in idiopathic FGR.

Placental biglycan expression is decreased in human idiopathic fetal growth restriction

Fetal growth restriction (FGR) is a leading cause of perinatal morbidity and mortality. The majority of FGR cases are idiopathic and are associated with placental insufficiency, which can result from placental thrombosis. Evidence suggests that Dermatan Sulfate (DS) is an important anti-coagulant in placentae of uncomplicated pregnancies. This study hypothesised that the expression of biglycan proteoglycan, a source of DS, is decreased in idiopathic FGR placentae compared with placentae from uncomplicated pregnancies. This study aimed to determine biglycan mRNA, protein expression and spatial distribution in idiopathic FGR placentae compared with the placentae from gestation-matched controls. Biglycan mRNA expression, protein expression and spatial distribution was determined in 26 idiopathic FGR-affected placentae and 27 placentae from gestation-matched controls (27-40 weeks gestation) using real-time PCR, immunoblotting and immunohistochemistry, respectively. Mean biglycan mRNA expression was significantly decreased in FGR placentae compared with control placentae (2.87 +/- 0.55, (n = 26) vs. 4.48 +/- 0.85, (n = 27); t-test p = 0.01). FGR placentae demonstrated a trend towards decrease in mean biglycan protein expression compared with control placentae (0.86 +/- 0.22 (n = 9, FGR) vs, 1.9 +/- 0.56 (n = 7, control) p = 0.07). Biglycan immunoreactivity was detected in endothelial cells and sub-endothelial cells of the perivascular region of fetal capillaries. Semi-quantitative analyses demonstrated a significant decrease in immunoreactive biglycan in FGR placentae compared with control placentae (51.1 +/- 19.3 vs, 500.7 +/- 223, n = 6, p < 0.001). This is the first study to demonstrate decreased biglycan expression in idiopathic FGR placentae compared to gestation-matched controls. Reduced biglycan expression may contribute to placental thrombosis within the fetal vasculature, and may contribute to the pathogenesis of idiopathic FGR.

Homeodomain protein HLX is expressed primarily in cytotrophoblast cell types in the early pregnancy human placenta

Homeobox genes are a large family of transcription factors. Of these, the HLX homeobox gene (previously known as HLX1 and HB24) is important for normal placentation. We have previously shown that HLX mRNA expression is significantly reduced in fetal growth-restricted human placentae compared with control placentae. In this study, a rabbit polyclonal antibody to the homeodomain protein HLX was raised and characterised. Western analysis revealed a protein of 50 kDa. HLX protein was detected in cellular nuclei in the cytotrophoblast-derived cell lines HTR8/SVneo, SGHPL-4, JEG-3, JAR and BeWo. Dual labelling with cytokeratin 7 was used to determine the spatial distribution of HLX in the early placenta and fetal membranes, showing both a perinuclear and punctate nuclear distribution for HLX. In the early pregnancy placenta HLX was localised to villous cytotrophoblast, and extravillous cytotrophoblast nuclei in the proximal regions of the cytotrophoblast cell columns, but was not detected at significant levels in the syncytiotrophoblast. In first trimester placental bed biopsies, HLX expression was not localised to the nucleus but instead was found in the cytoplasm. We conclude that HLX is primarily expressed in cytotrophoblast cell types in the human placenta and propose that HLX is involved in cytotrophoblast proliferation and downregulation of cell differentiation.

Homeobox genes and down-stream transcription factor PPARγ in normal and pathological human placental development

The placenta provides critical transport functions between the maternal and fetal circulations during intrauterine development. Formation of this interface is controlled by nuclear transcription factors including homeobox genes. Here we summarize current knowledge regarding the expression and function of homeobox genes in the placenta. We also describe the identification of target transcription factors including PPARγ, biological pathways regulated by homeobox genes and their role in placental development. The role of the nuclear receptor PPARγ, ligands and target genes in human placental development is also discussed. A better understanding of these pathways will improve our knowledge of placental cell biology and has the potential to reveal new molecular targets for the early detection and diagnosis of pregnancy complications including human fetal growth restriction.

Placental Syndecan Expression Is Altered in Human Idiopathic Fetal Growth Restriction

Pregnancy represents a hypercoagulable state characterized by increased thrombin generation. However, placentas from fetal growth restriction (FGR) pregnancies are characterized by increased fibrin deposition and thrombi in the vasculature, indicative of a further increase in thrombin activation and a disturbance in coagulation in this clinical setting. The cause of the coagulation disturbance observed in FGR pregnancies is currently unknown. Anticoagulant mechanisms are crucial in the regulation of thrombin activity, and current evidence suggests that syndecans are the principal placental anticoagulant proteoglycans. The aim of this study was to determine the localization, distribution, and expression of syndecans 1 to 4 in placentas complicated by idiopathic FGR compared with gestation-matched controls. Immunohistochemistry results revealed that all of the syndecans were localized to cells located closely to the maternal and fetal circulation. The mRNA and protein expression levels of both syndecan 1 and syndecan 2 were significantly decreased in FGR samples compared with controls. This is the first study to demonstrate the differential expression of syndecans 1 to 4 in idiopathic FGR placentas compared with controls. Reduced levels of syndecan expression may result in increased placental thrombosis in the uteroplacental circulation and may therefore contribute to the pathogenesis of FGR.

Homeobox Gene HLX Is a Regulator of HGF/c-met-Mediated Migration of Human Trophoblast-Derived Cell Lines

Homeobox gene transcription factors play a critical role in normal placental development and are expressed in specialized trophoblast cells. Abnormal trophoblast function is associated with clinically significant pregnancy disorders, including fetal growth restriction (FGR). Our previous studies demonstrated that homeobox gene HLX is expressed in proliferating and migrating (but not invading) human trophoblast cells and that HLX expression is significantly decreased in human FGR. We have also shown that HLX is a regulator of colony-stimulating-factor-1-dependent trophoblast proliferation. Hepatocyte growth factor (HGF) activates trophoblast cell migration in a paracrine fashion, and its receptor, c-met, is expressed on trophoblast cells. Given that HGF is a regulator of trophoblast migration, we hypothesize that HLX is a mediator of HGF/c-met-dependent trophoblast migration but not invasion. Here we investigated the potential role of HLX in HGF/c-met-mediated trophoblast migration and invasion in two human trophoblast-derived cell lines, SGHPL-4 and HTR-8/SVneo. Results showed that in cultured trophoblast cells, HGF stimulation significantly increased HLX mRNA and protein expression. HLX inactivation significantly decreased trophoblast migration but not invasion. When HLX was inactivated in the presence of HGF stimulation, migration remained significantly decreased. SU11274-mediated inhibition of the receptor c-met significantly decreased HLX mRNA and protein expression. In the presence of HGF stimulation, HLX expression remained significantly decreased with c-met inhibition. This is the first study to show that homeobox gene HLX is a downstream effector gene of HGF, that HLX regulates human trophoblast-derived cell migration, and that HGF, via receptor c-met, acts through HLX to control cell migration.

The Role of Homeobox Genes in the Development of Placental Insufficiency

Intrauterine growth restriction (IUGR) is an adverse pregnancy outcome associated with significant perinatal and pediatric morbidity and mortality, and an increased risk of chronic disease later in adult life. While a number of maternal, fetal and environmental factors are known causes of IUGR, the majority of IUGR cases are of unknown cause. These IUGR cases are frequently associated with placental insufficiency, possibly as a result of placental maldevelopment. Understanding the molecular mechanisms of abnormal placental development in IUGR associated with placental insufficiency is therefore of increasing importance. Here, we review our understanding of transcriptional control of normal placental development as well as human IUGR associated with placental insufficiency. We also assess the potential for understanding transcriptional control as a means for revealing new molecular targets for the detection, diagnosis and clinical management of IUGR associated with placental insufficiency.

The Role of Placental Homeobox Genes in Human Fetal Growth Restriction

Fetal growth restriction (FGR) is an adverse pregnancy outcome associated with significant perinatal and paediatric morbidity and mortality, and an increased risk of chronic disease later in adult life. One of the key causes of adverse pregnancy outcome is fetal growth restriction (FGR). While a number of maternal, fetal, and environmental factors are known causes of FGR, the majority of FGR cases remain idiopathic. These idiopathic FGR pregnancies are frequently associated with placental insufficiency, possibly as a result of placental maldevelopment. Understanding the molecular mechanisms of abnormal placental development in idiopathic FGR is, therefore, of increasing importance. Here, we review our understanding of transcriptional control of normal placental development and abnormal placental development associated with human idiopathic FGR. We also assess the potential for understanding transcriptional control as a means for revealing new molecular targets for the detection, diagnosis, and clinical management of idiopathic FGR.