Morphometric analysis of the branching of the vascular tree in the chick embryo area vasculosa.

The chick embryo includes the area vasculosa is subdivided into 2 concentric zones, the inner transparent area pellucida vasculosa and the surrounding less transparent area opaca vasculosa, peripherally limited by the sinus terminalis. In this study, we have analyzed by a modern morphometric approach the total length of the vascular network, the number of vascular branches, of the branching points density, the modality of vessel ramification, and spatial arrangement of the vascular network in four consecutive stages of development of the area vasculosa. The results have shown that there is a significant 15% increase in the total length of the vascular network associated with a progressive increase of the number of vascular branches and of the branching points density. Moreover, the results indicated that vascular spatial disorder significantly decreased during development in area vasculosa, suggesting a more uniform occupancy of the tissue by the vascular pattern. Finally, a more regular pattern of branching was observed, as indicated by the significant decrease of topological disorder of the vascular tree.

Matrix Gla Protein expression pattern in the early avian embryo.

MGP (Matrix Gla Protein) is an extracellular matrix vitamin K dependent protein previously identified as a physiological inhibitor of calcification and shown to be well conserved among vertebrates during evolution. MGP is involved in other mechanisms such as TGF-ß and BMP activity, and a proposed modulator of cell-matrix interactions. MGP is expressed early in vertebrate development although its role has not been clarified. Previous work in the chicken embryo found MGP localization predominantly in the aorta and aortic valve base, but no data is available earlier in development. Here we examined MGP expression pattern using whole-mount in situ hybridization and histological sectioning during the initial stages of chick development. MGP was first detected at HH10 in the head and in the forming dorsal aorta. At the moment of the onset of blood circulation, MGP was expressed additionally in the venous plexus which will remodel into the vitelline arteries. By E2.25, it is clear that the vitelline arteries are MGP positive. MGP expression progresses centrifugally throughout the area vasculosa of the yolk sac. Between stages HH17 and HH19 MGP is seen in the dorsal aorta, heart, notochord, nephric duct, roof plate, vitelline arteries and in the yolk sac, beneath main arterial branches and in the vicinity of several vessels and venules. MGP expression persists in these areas at least until E4.5. These data suggest that MGP expression could be associated with cell migration and differentiation and to the onset of angiogenesis in the developing chick embryo. This data has biomedical relevance by pointing to the potential use of chick embryo explants to study molecules involved in artery calcification.

Use of manipulated stem cells for prenatal therapy.

Prenatal stem cell therapy has broad potential for therapeutic application. "Stem cells" of interest include multipotent adult-derived stem cells, cord blood, amniotic fluid, or fetal stem cells, and embryonic or induced pluripotent stem cells. Potential manipulations of stem cells prior to their administration may include harvest, processing, enrichment, expansion, and genetic transduction. A complete description of the methodology related to all of the above is well beyond the scope of this chapter. In the interest of practical application and proven efficacy, we limit our description to adult-derived hematopoietic stem cells (HSCs) and their application to in utero transplantation with or without HSC-targeted gene transfer.

Animal models for prenatal gene therapy: rodent models for prenatal gene therapy.

Fetal gene transfer has been studied in various animal models, including rabbits, guinea pigs, cats, dogs, and nonhuman primate; however, the most common model is the rodent, particularly the mouse. There are numerous advantages to mouse models, including a short gestation time of around 20 days, large litter size usually of more than six pups, ease of colony maintenance due to the small physical size, and the relatively low expense of doing so. Moreover, the mouse genome is well defined, there are many transgenic models particularly of human monogenetic disorders, and mouse-specific biological reagents are readily available. One criticism has been that it is difficult to perform procedures on the fetal mouse with suitable accuracy. Over the past decade, accumulation of technical expertise and development of technology such as high-frequency ultrasound have permitted accurate vector delivery to organs and tissues. Here, we describe our experiences of gene transfer to the fetal mouse with and without ultrasound guidance from mid to late gestation. Depending upon the vector type, the route of delivery and the age of the fetus, specific or widespread gene transfer can be achieved, making fetal mice excellent models for exploratory biodistribution studies.

Thermal effect on heart rate and hemodynamics in vitelline arteries of stage 18 chicken embryos.

We investigated the thermal effects on heart rate, hemodynamics, and response of vitelline arteries of stage-18 chicken embryos. Heart rate was monitored by a high-speed imaging method, while hemodynamic quantities were evaluated using a particle image velocimetry (PIV) technique. Experiments were carried out at seven different temperatures (36-42 °C with 1 °C interval) after 1h of incubation to stabilize the heart rate. The heart rate increased in a linear manner (r = 0.992). Due to the increased cardiac output (or heart rate), the hemodynamic quantities such as mean velocity (U(mean)), velocity fluctuation (U(fluc)), and peak velocity (U(peak)) also increased with respect to the Womersley number (Ω) in the manner r = 0.599, 0.693, and 0.725, respectively. This indicates that the mechanical force exerting on the vessel walls increases. However, the active response (or regulation) of the vitelline arteries was not observed in this study.

Developmental changes in hemodynamics of uterine artery, utero- and umbilicoplacental, and vitelline circulations in mouse throughout gestation.

In human pregnancy, abnormal placental hemodynamics likely contribute to the etiology of early-onset preeclampsia and fetal intrauterine growth restriction. The mouse is increasingly being deployed to study normal and abnormal mammalian placental development, yet the placental hemodynamics in normal pregnancy in mice is currently unknown. We used ultrasound biomicroscopy to noninvasively image and record Doppler blood velocity waveforms from the maternal and embryonic placental circulations in mice throughout gestation. In the uterine artery, peak systolic velocity (PSV) increased significantly from 23+/-2 (SE) to 59+/-3 cm/s, and end-diastolic velocity (EDV) increased from 7+/-1 to 28+/-2 cm/s in nonpregnant versus full-term females so that the uterine arterial resistance index (RI) decreased from 0.70+/-0.02 to 0.53+/-0.02. Velocities in the maternal arterial canal in the placenta were low and nearly steady and increased from 0.9+/-0.03 cm/s at embryonic day 10.5 (E10.5) to 2.4+/-0.07 cm/s at E18.5. PSV in the umbilical artery increased steadily from 0.8+/-0.1 cm/s at E8.5 to 15+/-0.6 cm/s at E18.5, whereas PSV in the vitelline artery increased from 0.6+/-0.1 cm/s at E8.5 to 4+/-0.2 cm/s at E13.5 and then remained stable to term. In the umbilical artery, the EDV detection rate was 0% at

Chick chorioallantoic membrane as an in vivo model to study vasoreactivity: characterization of development-dependent hyperemia induced by epoxyeicosatrienoic acids (EETs).

Shell-less culture of chick chorioallantoic membrane (CAM) of developing chicken embryos is a useful model to evaluate the effects of vascular agents. We assessed the response of CAM vessels to epoxyeicosatrienoic acids (EETs), derivatives of the essential fatty acid arachidonic acid, that have a number of important biological functions, including dilation of microvessels in the coronary, cerebral, renal, and mesenteric circulations. Three of four regioisomers of EETs, 14,15-, 11,12-, and 8,9-EET, induced a characteristic dose-dependent acute hyperemia within 4 min after application on 10-day-old CAMs. This response was marked in early stages of development (between days 8 and 10), but the frequency and intensity of the response were reduced after 11 days of development. Histological examination demonstrated that the hyperemia was not due to extravasation of erythrocytes. However, many capillaries were distended and contained densely packed erythrocytes as compared to uniformly arranged vessels and erythrocytes in untreated CAMs. Transmission electron microscopy showed the basal laminae surrounding capillaries remained intact, similar to those in vehicle-treated or untreated CAM tissue. The hyperemia was specific to EETs since we did not observe it to be induced by other vasodilators such as nitric oxide or prostacyclin. In conclusion, we report a novel vascular response to EETs using the CAM as an in vivo model. These lipids specifically distend a subset of capillaries in a dose- and development-dependent manner.

Flow regulates arterial-venous differentiation in the chick embryo yolk sac.

Formation of the yolk sac vascular system and its connection to the embryonic circulation is crucial for embryo survival in both mammals and birds. Most mice with mutations in genes involved in vascular development die because of a failure to establish this circulatory loop. Surprisingly, formation of yolk sac arteries and veins has not been well described in the recent literature. Using time-lapse video-microscopy, we have studied arterial-venous differentiation in the yolk sac of chick embryos. Immediately after the onset of perfusion, the yolk sac exhibits a posterior arterial and an anterior venous pole, which are connected to each other by cis-cis endothelial interactions. To form the paired and interlaced arterial-venous pattern characteristic of mature yolk sac vessels, small caliber vessels of the arterial domain are selectively disconnected from the growing arterial tree and subsequently reconnected to the venous system, implying that endothelial plasticity is needed to fashion normal growth of veins. Arterial-venous differentiation and patterning are controlled by hemodynamic forces, as shown by flow manipulation and in situ hybridization with arterial markers ephrinB2 and neuropilin 1, which show that expression of both mRNAs is not genetically determined but plastic and regulated by flow. In vivo application of ephrinB2 or EphB4 in the developing yolk sac failed to produce any morphological effects. By contrast, ephrinB2 and EphB4 application in the allantois of older embryos resulted in the rapid formation of arterial-venous shunts. In conclusion, we show that flow shapes the global patterning of the arterial tree and regulates the activation of the arterial markers ephrinB2 and neuropilin 1.

Maternal diabetes: effects on embryonic vascular development--a vascular endothelial growth factor-A-mediated process.

Major congenital malformations, many of which result from abnormal cardiovascular patterning, remain the leading cause in infant mortality and morbidity. Targeted mutations of several genes (including VEGF and VEGF receptors) and certain teratogenic agents (including excess alpha-D-glucose) give rise to embryonic lethal phenotypes associated with failure in the formation of a functional vitelline circulation and aberrant organogenesis. Our work to date has demonstrated that yolk sac vasculopathy and failure of endocardial cushion epithelial-mesenchymal transformation occurs in hyperglycemic conditions in murine whole conceptus culture and in embryos from streptozotocin-induced diabetic mice. These cardiovascular abnormalities are associated with changes in expression and phosphorylation state of adhesion molecules such as platelet endothelial growth factor-1 and expression of growth factors such as vascular endothelial growth factor (VEGF-A). Further understanding of the effects of maternal diabetes on yolk sac and embryonic vasculogenesis/angiogenesis and organogenesis may lead to novel approaches in treating and preventing major birth defects.

Vascular abnormalities and elevated blood pressure in mice lacking adrenomedullin gene.

BACKGROUND: Adrenomedullin (AM) is a vasodilating peptide involved in the regulation of circulatory homeostasis and in the pathophysiology of certain cardiovascular diseases. Levels of AM are markedly increased in the fetoplacental circulation during pregnancy, although its function there remains unknown. To clarify the physiological functions of AM, we chose a gene-targeting strategy in mice. METHODS AND RESULTS: Targeted null mutation of the AM gene is lethal in utero: the mortality rate among AM(-/-) embryos was >80% at E13.5. The most apparent abnormality in surviving AM(-/-) embryos at E13.5 to E14.0 was severe hemorrhage, readily observable under the skin and in visceral organs. Hemorrhage was not detectable at E12.5 to E13.0, although the yolk sac lacked well-developed vessels. Electron microscopic examination showed endothelial cells to be partially detached from the basement structure at E12.5 in vitelline vessels and hepatic capillaries, which allowed efflux of protoerythrocytes through the disrupted barrier. The basement membrane was not clearly recognizable in the aorta and cervical artery, and the endothelial cells stood out from the wall of the lumen, only partially adhering to the basement structure. AM(+/-) mice survived to adulthood but exhibited elevated blood pressures with diminished nitric oxide production. CONCLUSIONS: AM is indispensable for the vascular morphogenesis during embryonic development and for postnatal regulation of blood pressure by stimulating nitric oxide production.

Definitive hematopoietic stem cells first develop within the major arterial regions of the mouse embryo.

The aorta-gonad-mesonephros (AGM) region is a potent hematopoietic site within the mammalian embryo body, and the first place from which hematopoietic stem cells (HSCs) emerge. Within the complex embryonic vascular, excretory and reproductive tissues of the AGM region, the precise location of HSC development is unknown. To determine where HSCs develop, we subdissected the AGM into aorta and urogenital ridge segments and transplanted the cells into irradiated adult recipients. We demonstrate that HSCs first appear in the dorsal aorta area. Furthermore, we show that vitelline and umbilical arteries contain high frequencies of HSCs coincident with HSC appearance in the AGM. While later in development and after organ explant culture we find HSCs in the urogenital ridges, our results strongly suggest that the major arteries of the embryo are the most important sites from which definitive HSCs first emerge.

Extraembryonic venous obstructions lead to cardiovascular malformations and can be embryolethal.

OBJECTIVE: To expand our knowledge concerning the effect of placental blood flow on human heart development, we used an embryonic chicken model in which extraembryonic blood flow was manipulated. METHODS: First, one of the three major vitelline veins was ligated, while blood flow was visualized with Indian ink. In this way, we could study the effect of different ligation positions on intracardiac flow patterns. Secondly, these vitelline veins were ligated permanently with a microclip until cardiac septation was completed, thereafter, the hearts were morphologically evaluated. In this way, we could study the impact of the ligation position on the severity and frequency of heart malformations. On combining the results, we were able to study the effect of different intracardiac flow patterns on heart development. RESULTS: Although ligation of each vein resulted in different intracardiac flow patterns, long-term ligation resulted in similar cardiovascular malformations in survivors. These consisted mainly of ventricular septum defects (VSDs), semilunar valve anomalies, and pharyngeal arch artery malformations. There was no significant difference (p > 0.05) between the ligation position and the incidence of cardiovascular malformations. However, the percentage mortality after clipping the left lateral vitelline vein was significantly higher (p < 0.05) than after ligation of either the right lateral or posterior vitelline vein. CONCLUSIONS: Early extraembryonic venous obstruction leads to altered flow patterns, which probably result in shear stress changes. In postseptation stages, these result in a spectrum of cardiovascular malformations irrespective of the ligation position. A diminished incidence of VSDs in the oldest stage was attributed to delayed closure of the interventricular foramen.

Hyperglycemia-induced vasculopathy in the murine vitelline vasculature: correlation with PECAM-1/CD31 tyrosine phosphorylation state.

Maternal diabetes mellitus is associated with an increased incidence of congenital abnormalities as well as embryonic and perinatal lethality. In particular, a wide range of cardiovascular abnormalities have been noted in children of diabetic mothers and in the offspring of diabetic animals. The vascular system is the first organ system to develop in the embryo and is critical for normal organogenesis. The organization of mesodermal cells into endothelial and hematopoietic cells and into a complex vascular system is, in part, mediated by a series of specific cell-cell, cell-extracellular matrix, and cell-factor interactions. PECAM-1 expression has been observed during the earliest stages of vasculogenesis, and changes in PECAM-1 tyrosine phosphorylation have been associated with endothelial cell migration, vasculogenesis, and angiogenesis both in vitro and in vivo. In this report we demonstrate that exposure to hyperglycemia during gastrulation causes yolk sac and embryonic vasculopathy in cultured murine conceptuses and in the conceptuses of streptozotocin-induced diabetic pregnant mice. In addition, we correlate the presence of yolk sac and embryonic vasculopathy with the failure of PECAM-1 tyrosine dephosphorylation during the formation of blood islands/vessels from clusters of extra-embryonic and embryonic angioblasts in the murine conceptus using both in vitro and in vivo models. The importance of these findings in the development of vasculopathy in the offspring of diabetic mothers and the potential effects and benefits of glucose regulation during the periods of vasculogenesis/angiogenesis in embryonic development are discussed.

2,3,7,8-Tetrachlorodibenzo-p-dioxin alters cardiovascular and craniofacial development and function in sac fry of rainbow trout (Oncorhynchus mykiss).

Hallmark signs of 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) toxicity in rainbow trout sac fry, are yolk sac edema, hemorrhage, craniofacial malformation, and growth retardation culminating in mortality. Our objective was to determine the role of cardiovascular dysfunction in the development of this toxicity. An embryotoxic TCDD dose (385 pg/g egg) caused a progressive reduction in blood flow in rainbow trout sac fry manifested first and most dramatically in the 1st and 2nd branchial arches and vessels perfusing the lower jaw. Blood flow was reduced later in the infraorbital artery and occipital vein of the head as well as segmental vessels and caudal vein of the trunk. Reduced perfusion occurred last in gill branchial arteries involved with oxygen uptake and the subintestinal vein and vitelline vein involved with nutrient uptake. Although heart rate throughout sac fry development was not affected, heart size at 50 days post-fertilization (dpf) was reduced far more than body weight or length, suggesting that the progressive circulatory failure caused by TCDD is associated with reduced cardiac output. Craniofacial development was arrested near hatch, giving rise to craniofacial malformations in which the jaws and anterior nasal structures were underdeveloped. Unlike the medaka embryo, in which TCDD causes apoptosis in the medial yolk vein, endothelial cell death was not observed in rainbow trout sac fry. These findings suggest a primary role for arrested heart development and reduced perfusion of tissues with blood in the early-life stage toxicity of TCDD in trout.

Unsuspected role for the T-cell leukemia protein SCL/tal-1 in vascular development.

The transcription factor SCL/tal-1 is essential for blood cell development. Though it is also expressed in vascular endothelium, SCL has been considered dispensable for vessel formation. Through transgenic rescue of hematopoietic defects of SCL-/- embryos and analysis of chimeras generated with SCL-/- ES cells tagged with a transgene expressed in vascular endothelial cells, we show that SCL is essential for angiogenic remodeling of the yolk sac capillary network into complex vitelline vessels. These findings establish a role for SCL in embryonic angiogenesis and argue for critical functions in both embryonic blood and vascular cells, the descendents of the presumptive hemangioblast.

The role of maternally derived epidermal growth factor and the epidermal growth factor receptor during organogenesis in the rat embryo.

Epidermal growth factor (EGF) has been implicated in the control of embryonic development, but although the receptor is expressed from an early stage, there is little evidence of embryonic expression of EGF. In order to investigate the role of maternally derived EGF during organogenesis, rat embryos were explanted at d 9.5 and cultured in serum depleted of low molecular weight molecules (retenate) which was then supplemented with EGF. Serum depleted of low molecular weight molecules by prolonged filtration loses its capacity to support normal embryonic development, possibly due to the loss of growth promoting factors. The addition of EGF to retenate significantly improved embryonic development with a maximal effect at 8 ng/ml. The addition of an analogue of EGF, long EGF, to retenate also caused a significant increase in development, although at higher concentrations a decrease in its effect was observed, possibly due to down regulation of the EGF receptor. Therefore, embryos may be able to utilise maternally derived EGF during organogenesis. To test the effects of inhibiting the EGF receptor during organogenesis, d 9.5 embryos were cultured in the presence of tyrphostin 47, a specific EGF receptor inhibitor. Tyrphostin 47 caused a significant dose-dependent decrease in the development of embryos which was also observed when tyrphostin 47 was injected into the vitelline circulation at d 11.5 to bypass the effects of the yolk sac. These findings suggest that the EGF receptor is essential for normal organogenesis and may play a role in the control of proliferation and differentiation. Although EGF is not expressed in the rat embryo at this stage, maternally derived EGF may be the ligand for the embryonic EGF receptor.

11.5-day rat embryos cultured in vitro after introduction of immunoglobulin G into the vitelline circulation.

The fate of rat immunoglobulin G (IgG) in the 11.5-day-rat conceptus cultured in vitro has been studied utilizing the intravitelline cannulation technique. When IgG bound to colloidal gold was introduced into the vitelline circulation, gold particles were detected on the luminal surface of embryonic endothelial cells, in both coated pits and vesicles and in various portions of the vacuolar system of the embryonic endothelial cell. By means of the radiolabeled macromolecule, it has been demonstrated that the internalized IgG was not degraded. In comparison, digested products of radiolabeled bovine serum albumin (BSA) were detected in culture media after the macromolecule was introduced into the conceptus. It was therefore concluded that the 11.5-day rat embryo captures IgG probably by receptor-mediated endocytosis and does not degrade the macromolecule, indicating that IgG is not routed to the lysosomal compartment of the endothelial cell even though the embryo has the capacity to digest BSA. It appears therefore that the embryo is endowed with the capacity to handle the IgG macromolecule well before the macromolecule is introduced into it for passive immunity.

Maternal-fetal potential difference in the rat is generated by the placenta.

Electrical potential difference, PD, was recorded between maternal blood on one side and uterine lumen (transuterine PD), amniotic fluid (amniotic fluid PD), or vitelline blood of the fetus (maternal-fetal PD) on the other side in rats on day 21 of gestation. The values obtained are 2.4 +/- 6.0 mV (mean +/- s.e.), 11.3 +/- 4.5 mV and 9.6 +/- 4.1 mV, respectively. Maternal-fetal PD recorded over a period of 12 min decreased slowly. It increased transiently when the placenta was separated from the uterus, then it decreased more rapidly than in the corresponding controls afterwards. Maternal-fetal PD did not change significantly when the sac of fetal membranes containing the fetus was exposed intact from the uterus. In other experiments the PD was recorded in vitro between vitelline blood of the fetus which had been removed from the uterus together with intact sac of fetal membranes and a bath of Ringer solution. The PD recorded when only the exposed surface of the placenta (the surface by which the placenta had been attached to the uterus) was immersed in Ringer fluid, was the same as that recorded earlier between maternal and fetal blood in the same fetus. The PD decreased rapidly when the placenta was cooled, and it increased again when the placenta was rewarmed. The PD decreased to near 0 mV when the whole sac of fetal membranes was immersed in Ringer. On the basis of these observations it is concluded that the maternal-fetal PD in the rat is generated by the placenta.

Distribution of blood flow between embryo and vitelline bed in the stage 18, 21 and 24 chick embryo.

OBJECTIVE: We defined the distribution of blood flow between the embryo and the extraembryonic vascular bed as an initial step in understanding the control of flow distribution in the early developing heart. METHODS: Dorsal aortic blood flow of stage 18, 21, and 24 chick embryo (n > or = 7 at each stage) was measured with a 20 MHz pulsed-Doppler velocity meter. Analog waveforms were digitally sampled at 500 Hz. 1-5 x 10(3) yellow microspheres in saline suspension were injected into the vitelline vein. The embryo and the extraembryonic vascular bed were harvested and separated from each other. The dye on the microspheres from each portion was extracted and extrapolated from the standard curve of the absorbance of dye concentrations per number of microspheres quantified by spectrophotometry. Blood flow was calculated from the integral of blood velocity and aortic cross-sectional area multiplied by the fraction distribution of microspheres in the embryo and extraembryonic vascular bed. Data were presented as mean +/- standard error of the mean. RESULTS: The proportion distribution of microspheres between embryo and extraembryonic vascular bed shifted from 18.7 +/- 2.5 vs. 81.3 +/- 2.5% at stage 18, 25.1 +/- 3.0 vs. 74.9 +/- 3.0% at stage 21, and 34.2 +/- 2.4 vs. 65.8 +/- 2.4% at stage 24. Indices of blood flow normalized to wet weight (mean +/- 95% confidence interval) were similar between the embryo and the extraembryonic vascular bed, but increased throughout the stages. CONCLUSION: During embryogenesis, blood flow per unit mass is evenly distributed between the metabolically active embryo and the extraembryonic vascular bed.

Early embryonic angiogenesis in the chick area vasculosa.

The rate and pattern of growth as well as vessel ultrastructure of the area vasculosa were examined in the chick. The embryos were grown in shell-less culture after 3 d in ovo and staged according to Hamburger & Hamilton (1951) and the rate of increase in the diameter of the area vasculosa was measured. This revealed an increase in the area vasculosa diameter of 0.4 +/- 0.02 mm h-1 (n = 62) for embryos between stages 15 and 20. To determine the growth pattern of the sinus terminalis (the advancing edge of the area vasculosa), a marked length of the sinus was photographed at hourly intervals over a period of 9 h. It was found that this vessel grows by new vessels forming external to the sinus in the form of parallel plexuses, one of which then replaces the original sinus as the major route of bloodflow. Ultrastructurally the capillaries of the area vasculosa were simple tubes of endothelial cells, lacking a basement membrane. The endothelial cell cytoplasm contained only a few organelles, mainly mitochondria and rough endoplasmic reticulum. These findings indicate that the chick area vasculosa capillaries bear similar structural and growth characteristics to those associated with tumour angiogenesis and suggest that they may prove to be a useful model system for studying the factors involved in pathological angiogenesis.