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.     

Comparative Response of Rat and Rabbit Conceptuses In Vitro to Inhibitors of Histiotrophic Nutrition

Histiotrophic nutrition via the visceral yolk sac is an essential nutritional pathway of the rodent conceptus, and inhibition of this pathway may cause growth retardation, malformations, and death in rodent embryos. Morphologic differences among species during early development indicate that the visceral yolk sac histiotrophic nutrition pathway may be of lesser importance in nonrodent species, including humans. Here, comparative studies were conducted with inhibitors of different steps in the visceral yolk sac histiotrophic nutrition pathway to determine whether the rabbit is similarly responsive to the rat. Early somite stage New Zealand White rabbit and Crl:CD(SD) rat conceptuses (gestation day 9, rabbits; gestation day 10, rats) were exposed for 48 hr to three different histiotrophic nutrition pathway inhibitors using whole embryo culture techniques, after which they were evaluated for growth and malformations. Cubilin antibody, an inhibitor of endocytosis, reduced growth and development and increased malformations in both rat and rabbit embryos, although the rabbit appeared more sensitive. Leupeptin, a lysosomal cysteine protease inhibitor, also impaired growth and development and increased malformations in rat embryos, while in the rabbit it induced malformations and a slight decrease in morphology score but had no effect upon growth. Trypan blue, an inhibitor of endocytosis and endosome maturation, affected all measures in both species to a similar degree at the highest concentration (2500 μg/ml), but rat embryos responded to a greater extent at lower concentrations. Although the specific adverse outcomes appear to be different, these results demonstrate that rabbits, like rats, are sensitive to inhibitors of the histiotrophic nutrition pathway     

Yolk sac development in lizards (Lacertilia: Scincidae): New perspectives on the egg of amniotes

Embryos of oviparous reptiles develop on the surface of a large mass of yolk, which they metabolize to become relatively large hatchlings. Access to the yolk is provided by tissues growing outward from the embryo to cover the surface of the yolk. A key feature of yolk sac development is a dedicated blood vascular system to communicate with the embryo. The best known model for yolk sac development and function of oviparous amniotes is based on numerous studies of birds, primarily domestic chickens. In this model, the vascular yolk sac forms the perimeter of the large yolk mass and is lined by a specialized epithelium, which takes up, processes and transports yolk nutrients to the yolk sac blood vessels. Studies of lizard yolk sac development, dating to more than 100 years ago, report characteristics inconsistent with this model. We compared development of the yolk sac from oviposition to near hatching in embryonic series of three species of oviparous scincid lizards to consider congruence with the pattern described for birds. Our findings reinforce results of prior studies indicating that squamate reptiles mobilize and metabolize the large yolk reserves in their eggs through a process unknown in other amniotes. Development of the yolk sac of lizards differs from birds in four primary characteristics, migration of mesoderm, proliferation of endoderm, vascular development and cellular diversity within the yolk sac cavity. Notably, all of the yolk is incorporated into cells relatively early in development and endodermal cells within the yolk sac cavity align along blood vessels which course throughout the yolk sac cavity. The pattern of uptake of yolk by endodermal cells indicates that the mechanism of yolk metabolism differs between lizards and birds and that the evolution of a fundamental characteristic of embryonic nutrition diverged in these two lineages. Attributes of the yolk sac of squamates reveal the existence of phylogenetic diversity among amniote lineages and raise new questions concerning the evolution of the amniotic egg. J. Morphol. 278:574–591, 2017. © 2017 Wiley Periodicals, Inc.     

Yolk sac: site of developmental microheterogeneity of mouse alpha-fetoprotein.

α-Fetoprotein was observed to be synthesized in mouse fetal liver and yolk sac by incorporation of radioactive leucine into appropriate tissue cultures. Cultured fetal liver during early (Day 13.5) and late (Day 16.5) development secreted predominantly the maximally sialylated Fp5. In contrast, the yolk sac secreted a developmentally changing array of α-fetoprotein: Day 11.5 yolk sac secreted predominantly the unsialylated Fp1, at Day 13.5, the yolk sac secreted all five electrophoretic forms of α-fetoprotein, and by Day 16.5, only Fp5 was predominantly secreted, as in the fetal liver. To ascertain whether the ³H-labeled proteins that appeared in the regions of α-fetoprotein on polyacrylamide gels represented α-fetoprotein, immunoprecipitations with anti-α-fetoprotein were carried out. After the immunoprecipitations, radioactivity in the regions of marker α-fetoprotein on polyacrylamide gels was decreased to background levels. When sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the immunoprecipitates was performed, radioactivity peaks comigrated with marker α-fetoprotein. The undersialylated α-fetoprotein forms do not appear to arise by loss of sialic acid following secretion as determined by mixing experiments of yolk sac and fetal liver in culture. The contribution of α-fetoprotein synthesized and secreted by fetal liver and yolk sac at Days 13.5 and 16.5 of development was compared. Day 13.5 yolk sac incorporated 6.7 times as much radioactivity into secreted α-fetoprotein as did fetal liver at this time. These results suggest that during early development, the yolk sac is primarily responsible for the synthesis and secretion of the undersialylated forms of α-fetoprotein. In addition to the microheterogeneity of α-fetoprotein attributed to the number of sialic acid residues attached to the glycoprotein, there appeared to be other changes in α-fetoprotein: Fp5 synthesized from fetal liver migrated slightly faster on polyacrylamide gels than that from yolk sac.     

Embryonic macrophages of early rat yolk sac: Immunohistochemistry and ultrastructure with reference to endodermal cell layer

Macrophages are multifunctional cells that participate in numerous biological processes; they actively phagocytose foreign particles and cell debris. Embryonic tissue macrophages are present at early stages of mammalian development; their ontogeny and function is still under investigation. Our study used immunohistochemistry and electron microscopy to investigate early rat yolk sac macrophages using mouse antirat macrophage monoclonal antibodies (mAb) Mar 1 and Mar 3 produced by our laboratory. Mar 3 mAb revealed the first emergence of immature macrophages in the rat yolk sac at fetal day nine coinciding with the beginning of yolk sac haemopoiesis that consisted mainly of erythropoiesis, while Mar 1 mAb detected specifically rat yolk sac macrophages at about the 13th to 14th day of gestation. Immunoreactivity against Mar mAbs was mainly located in the yolk sac endodermal cell layer, which may signify endodermal origin of the yolk sac macrophages. Ultrastructurally mature yolk sac macrophages contained numerous endocytic vesicles or vacuoles, well-developed Golgi saccules and many electron dense granules in their cytoplasm and a number of microvillous projections from the cell surface. After establishment of the circulation between yolk sac and embryo, Mar 3 positive cells were also demonstrated inside fetal undifferentiated mesenchymal tissue at fetal day 12. The study demonstrated the first emergence of immature yolk sac macrophages being among the earliest haemopoietic cells formed in mammalian development. Thus, Mar mAbs managed to detect macrophage differentiation antigens through their development early in the rat yolk sac.     

Development of erythroid and myeloid progenitors in the yolk sac and embryo proper of the mouse.

In this study, we have mapped the onset of hematopoietic development in the mouse embryo using colony-forming progenitor assays and PCR-based gene expression analysis. With this approach, we demonstrate that commitment of embryonic cells to hematopoietic fates begins in proximal regions of the egg cylinder at the mid-primitive streak stage (E7.0) with the simultaneous appearance of primitive erythroid and macrophage progenitors. Development of these progenitors was associated with the expression of SCL/tal-1 and GATA-1, genes known to be involved in the development and maturation of the hematopoietic system. Kinetic analysis revealed the transient nature of the primitive erythroid lineage, as progenitors increased in number in the developing yolk sac until early somite-pair stages of development (E8.25) and then declined sharply to undetectable levels by 20 somite pairs (E9.0). Primitive erythroid progenitors were not detected in any other tissue at any stage of embryonic development. The early wave of primitive erythropoiesis was followed by the appearance of definitive erythroid progenitors (BFU-E) that were first detectable at 1-7 somite pairs (E8.25) exclusively within the yolk sac. The appearance of BFU-E was followed by the development of later stage definitive erythroid (CFU-E), mast cell and bipotential granulocyte/macrophage progenitors in the yolk sac. C-myb, a gene essential for definitive hematopoiesis, was expressed at low levels in the yolk sac just prior to and during the early development of these definitive erythroid progenitors. All hematopoietic activity was localized to the yolk sac until circulation was established (E8.5) at which time progenitors from all lineages were detected in the bloodstream and subsequently in the fetal liver following its development. This pattern of development suggests that definitive hematopoietic progenitors arise in the yolk sac, migrate through the bloodstream and seed the fetal liver to rapidly initiate the first phase of intraembryonic hematopoiesis. Together, these findings demonstrate that commitment to hematopoietic fates begins in early gastrulation, that the yolk sac is the only site of primitive erythropoiesis and that the yolk sac serves as the first source of definitive hematopoietic progenitors during embryonic development.     

Presence of mast cell precursors in the yolk sac of mice

Concentration of mast-cell precursors in hematopoietic tissues of mouse embryos was evaluated by a limiting dilution method. Cells from yolk sacs, livers, and bodies of (WB x C57BL/6)F1 (hereafter called WBB6F1)- +/+ embryos were injected directly into the skin of adult WBB6F1-W/Wv mice which were genetically depleted of tissue mast cells. Concentration of mast-cell precursors was calculated from the proportion of injection sites at which mast cells did not appear. Since the concentration of mast-cell precursors in the yolk sac was about 30 times as great as that of embryonic body at Day 9.5 of the pregnancy, the mast-cell precursors seemed to be generated within the yolk sac. The concentration in the yolk sac reached the maximum level at Day 11, and then dropped markedly at Day 13. In contrast, mast-cell precursors increased from Day 11 to Day 15 in the fetal liver. As a result, the concentration of 11-day yolk sacs was comparable to that of 15-day fetal liver. Although intravenous injection of 15-day fetal liver cells (2 x 10(6)) rescued the general mast-cell depletion of WBB6F1-W/Wv mice, the intravenous injection of the same number of 11-day yolk sac cells did not rescue it. In contrast with fetal livers, yolk sacs scarcely contained hematopoietic stem cells which were measured by spleen colony formation. Therefore, the mast-cell precursors of the yolk sac may not originate from such stem cells.     

The rat visceral yolk sac internalizes maternal transferrin and secretes hydrolyzed products towards the fetus

The uptake of transferrin by the rat visceral yolk sac membranes, and the fate of this protein, were measured in a two-chambered system which allowed access to both surfaces of these membranes, i.e. that facing the maternal compartment and that facing the fetal compartment. 125I-labeled transferrin was internalized by the maternal surface of the visceral yolk sac but not by the fetal surface. Following internalization, this transferrin was degraded and the amino acids were secreted exclusively towards the fetal compartment. Transcytosis of intact transferrin was not detected in either direction. These results suggest that transport across the rat visceral yolk sac bound to maternally derived transferrin is not a major mechanism of iron transport in vivo. These results support a role for the visceral yolk sac in fetal metabolism, or supplying the fetus with amino acids derived from degradation of specific maternal plasma proteins, in this case, transferrin.     

Apolipoprotein B-related gene expression and ultrastructural characteristics of lipoprotein secretion in mouse yolk sac during embryonic development.

In mice, the yolk sac appears to play a crucial role in nourishing the developing embryo, especially during embryonic days (E) 7;-10. Lipoprotein synthesis and secretion may be essential for this function: embryos lacking apolipoprotein (apo) B or microsomal triglyceride transfer protein (MTP), both of which participate in the assembly of triglyceride-rich lipoproteins, are apparently defective in their ability to export lipoproteins from yolk sac endoderm cells and die during mid-gestation. We therefore analyzed the embryonic expression of apoB, MTP, and alpha-tocopherol transfer protein (alpha-TTP), which have been associated with the assembly and secretion of apoB-containing lipoproteins in the adult liver, at different developmental time points. MTP expression or activity was found in the yolk sac and fetal liver, and low levels of activity were detected in E18.5 placentas. alpha-TTP mRNA and protein were detectable in the fetal liver, but not in the yolk sac or placenta. Ultrastructural analysis of yolk sac visceral endoderm cells demonstrated nascent VLDL within the luminal spaces of the rough endoplasmic reticulum and Golgi apparatus at E7.5 and E8.5. The particles were reduced in diameter at E13.5 and reduced in number at E18.5;-19.The data support the hypothesis that the yolk sac plays a vital role in providing lipids and lipid-soluble nutrients to embryos during the early phases (E7;-10) of mouse development. secretion in mouse yolk sac during embryonic development.     

The carnivore pregnancy: the development of the embryo and fetal membranes

The aim of this research was to compare the morphological aspects during the development of pregnancy in dogs and cats, distinguishing features of the fetal membranes, such as yolk sac evolution and differentiation of hemangioblasts, and the degree of elaboration of the amnion and allantois. Canine and feline placentae from 20, 24, 35, 45 and 55 d of pregnancy were perfusion-fixed for histological investigation and vascular corrosion casts were produced. The casts were prepared for scanning electron microscopy (SEM) and the embryo and fetal membrane development was analyzed. The growth patterns of the conceptuses were compared with the organization of the placentation process, and changes of the morphology during pregnancy were recorded. In feline placentae, an incomplete zonary shape was present in 62.5% out of 60 studied cases. This was located distal to the insertion of the umbilical cord. In the lamellar zone, the interhemal membrane or placental barrier resembled endotheliochorial conditions, and the maternal-fetal microvascular blood flow interrelationship was of simple crosscurrent type. Dogs have a zonary placenta, completely surrounding the fetus, and complex lamellar organization of maternal and fetal tissues. At the border, two marginal hematomes with green colouration delimited the central placental girdle. The yolk sac consisted of one large sacculation with an inverted "T" shape and an enormous number of blood vessels; it had hemangioblast cells in contact with the epithelium. The amnion was avascular in early stages, but became vascularized by blood vessels of the internal allantoic membrane in later stages of pregnancy by intrinsic relation.     

Experimental yolk sac dysfunction as a model for studying nutritional disturbances in the embryo during early organogenesis

Our investigations concerning the importance of cell surface macromolecules during embryonic development led us to the discovery in 1961 that heterologous anti-rat kidney serum produced teratogenesis, growth retardation and embryonic death when injected into the pregnant rat during early organogenesis. It was established that IgG was the teratogenic agent, primarily directed against the visceral yolk sac (VYS) but not the embryo. Heterologous anti-rat VYS serum was prepared which was teratogenic localized in the VYS and served as a model for producing VYS dysfunction and embryonic malnutrition. The role of the yolk sac placenta in histiotrophic nutrition is now recognized to be critical for normal embryonic development during early organogenesis in the rodent. VYS antiserum affects embryonic development primarily by inhibiting endocytosis of proteins by the VYS endoderm, resulting in a reduction in the amino acids supplied to the embryo. Our laboratory has recently developed teratogenic monoclonal yolk sac antibodies (MCA) which can be utilized; to study VYS plasma membrane synthesis and recycling, to compare yolk sac function among different species, and to identify components of the plasma membrane involved in pinocytosis. MCA prepared against certain VYS antigens provide an opportunity to study embryonic nutrition with minimal interference with the nutritional state of the mother. Recent developments in the study of the human yolk sac along with our laboratory's ability to isolate a spectrum of yolk sac antigens, prepare monoclonal antibodies, and perform functional studies, should provide information that will increase our understanding of yolk sac function and dysfunction in the human and determine the relative importance of various amino acids to normal development during mammalian organogenesis.     

An electron microscopic study of absorption of peroxidase-conjugated immunoglobulin G by guinea pig visceral yolk sac in vitro.

In the guinea pig and some other animals, passive immunity is conferred on the developing fetus by passage of immunoglobulin from mother to fetus across the yolk sac. In order to examine the cytological pathway involved in immunoglobulin transport, guinea pig visceral yolk sacs from late in gestation were exposed in vitro to peroxidase-conjugated guinea pig immunoglobulin G (IgG-HRP). Tissue was then fixed, incubated to show the site of localization of peroxidase reaction product and prepared for electron microscopy. The results suggested that the first step in the uptake of IgG-HRP by yolk sac is attachment of the protein to the surface coats of endocytic invaginations at the apical surfaces of the endodermal cells. The endocytic vesicles then appear to pinch off from the surface and move deeper into the cytoplasm. Some of the small endocytic vesicles fuse with large apical vacuoles, which often contain large amounts of reaction product. Other small endocytic vesicles pinch off from the surface, move deeper into the cytoplasm and fuse with the lateral plasmalemma; their protein content is emptied into the intercellular space by exocytosis. From the intercellular spaces the protein presumably diffuses across the basement membrane and connective tissue spaces and enters the vitelline capillary bed. It is postulated that the latter cellular pathway, involving small vesicles and the intercellular spaces, is utilized by those immunoglobulins which are transferred intact across the yolk sac endoderm.     

Mechanisms regulating toxicant disposition to the embryo during early pregnancy: an interspecies comparison

The dose of toxicant reaching the embryo is a critical determinant of developmental toxicity, and is likely to be a key factor responsible for interspecies variability in response to many test agents. This review compares the mechanisms regulating disposition of toxicants from the maternal circulation to the embryo during organogenesis in humans and the two species used predominantly in regulatory developmental toxicity testing, rats and rabbits. These three species utilize fundamentally different strategies for maternal-embryonic exchange during early pregnancy. Early postimplantation rat embryos rely on the inverted visceral yolk sac placenta, which is in intimate contact with the uterine epithelium and is equipped with an extensive repertoire of transport mechanisms, such as pinocytosis, endocytosis, and specific transporter proteins. Also, the rat yolk sac completely surrounds the embryo, such that the fluid-filled exocoelom survives through most of the period of organogenesis, and can concentrate compounds such as certain weak acids due to pH differences between maternal blood and exocelomic fluid. The early postimplantation rabbit conceptus differs from the rat in that the yolk sac is not closely apposed to the uterus during early organogenesis and does not completely enclose the embryo until relatively later in development (approximately GD13). This suggests that the early rabbit yolk sac might be a relatively inefficient transporter, a conclusion supported by limited data with ethylene glycol and one of its predominant metabolites, glycolic acid, given to GD9 rabbits. In humans, maternal-embryo exchange is thought to occur via the chorioallantoic placenta, although it has recently been conjectured that a supplemental route of transfer could occur via absorption into the yolk sac. Knowledge of the mechanisms underlying species-specific embryonic disposition, factored together with other pharmacokinetic characteristics of the test compound and knowledge of critical periods of susceptibility, can be used on a case-by-case basis to make more accurate extrapolations of test animal data to the human.     

Formation sites and distribution of osteoclast progenitor cells during the ontogeny of the mouse

The presence of osteoclast progenitor cells in embryonic, fetal, young growing, and adult murine tissues and organs was investigated in a coculture system with fetal metatarsal bones stripped of periosteum and not yet invaded by osteoclasts. Osteoclasts were found to originate from the early yolk sac and from every tissue tested in the fetus and young mouse. In the adult mouse they were formed only from tissues with a large mononuclear phagocyte population. No osteoclasts could be generated from the young embryo proper, prior to establishment of the vascular connection with the yolk sac. Progenitors of osteoclasts or their stem cells therefore do not develop from undifferentiated mesenchyme outside the yolk sac, but are distributed from the yolk sac to embryonic tissues and hematopoietic organs through the vascular circulation. The embryonic distribution of osteoclast progenitors coincides with the distribution of immature macrophages. Furthermore, they are present before the formation of monocytes in the fetus. The results also indicate that osteoclast precursor cells are not identical with mature, differentiated macrophages, but are cells with little capacity to phagocytose and therefore are, at the most immature progenitors of macrophages or cells of an early diverging lineage. In view of these results the derivation of osteoclasts is discussed.     

Isolation and characterization of the Fc receptor from the fetal yolk sac of the rat

The yolk sac of the fetal rat and the proximal small intestine of the neonatal rat selectively transport maternal IgG. IgG-Fc receptors are thought to mediate transport across the epithelium of both tissues. We used a mouse mAb (MC-39) against the 45-54-kD component of the Fc receptor of the neonatal intestine to find an antigenically related protein that might function as an Fc receptor in fetal yolk sac. In immunoblots of yolk sac, MC-39 recognized a protein band with apparent molecular mass of 54-58 kD. MC-39 bound to the endoderm of yolk sac in immunofluorescence studies. In immunogold-labeling experiments MC-39 was associated mainly with small vesicles in the apical cytoplasm and in the region near the basolateral membrane of endodermal cells. The MC- 39 cross-reactive protein and beta 2-microglobulin, a component of the intestinal Fc receptor, were copurified from detergent-solubilized yolk sac by an affinity purification that selected for proteins which, like the intestinal receptor, bound to IgG at pH 6.0 and eluted at pH 8.0. In summary, the data suggest that we have isolated the Fc receptor of the yolk sac and that this receptor is structurally and functionally related to the Fc receptor of the neonatal intestine. An unexpected finding is that, unlike the intestinal receptor which binds maternal IgG on the apical cell surface, the yolk sac receptor appears to bind IgG only within apical compartments which we suggest represent the endosomal complex.     

Maternal high density lipoproteins affect fetal mass and extra-embryonic fetal tissue sterol metabolism in the mouse

Previous studies have shown that antibodies to cubulin, a receptor on the yolk sac that binds high density lipoproteins (HDL) and cobalamin, induce fetal abnormalities. Mice with markedly low concentrations of plasma HDL-cholesterol (HDL-C) give birth to healthy pups, however. To establish whether maternal HDL-C has a role in fetal development, sterol metabolism was studied in the fetus and extra-embryonic fetal tissues in wild-type and apolipoprotein A-I-deficient mice (apoAI-/-). Maternal HDL-C content was markedly greater in apoAI+/+ mice prior to pregnancy and at 13 days into gestation. By 17 days into gestation, HDL-C content was similar between both types of mice. Fetuses from apoAI (-/- x -/-) matings were 16;-25% smaller than control mice at 13 and 17 days of gestation and contained less cholesterol. The differences in size and cholesterol content were not due to a lack of cholesterol synthesis or apoA-I in the fetus. In the yolk sac and placenta, sterol synthesis rates were approximately 50% greater in the 13-day-old apoAI-/- mice as compared to the apoAI+/+ mice. Even though synthesis rates were greater, cholesterol concentrations were 22% lower in the yolk sac and similar in the placenta of apoAI-/- mice as compared to tissues of wild-type mice. These data suggest that a difference in maternal HDL-C concentration or composition can affect the size of the fetus and sterol metabolism of the yolk sac and placenta in the mouse.     

In vitro development of murine T cells from prethymic and preliver embryonic yolk sac hematopoietic stem cells.

Mature T cells are derived from prethymic stem cells, which arise at one or more extrathymic sites and enter and differentiate in the thymus. The nature of these prethymic stem cells is a critical factor for the formation of the T-cell repertoire. Although the bone marrow of adult mice can provide such stem cells, their origin during murine embryogenesis is still undetermined. Among potential sites for these progenitor cells are the fetal liver and the embryonic yolk sac. Our studies focus on the yolk sac, both because the yolk sac appears earlier than any other proposed site, and because the mammalian yolk sac is the first site of hematopoiesis. Although it has been shown that the yolk sac in midgestation contains stem cells that can enter the thymic rudiment and differentiate toward T-cell lineage, our aim was to analyze the developmental potential of cells in the yolk sac from earlier stages, prior to the formation of the liver and any other internal organ. We show here that the yolk sac from 8- and 9-day embryos (2-9 and 13-19 somites, respectively) can reconstitute alymphoid congenic fetal thymuses and acquire mature T-cell-specific characteristics. Specifically, thymocytes derived from the early embryonic yolk sac can progress to the expression of mature T lymphocyte markers including CD3/T-cell receptor (TCR), CD4 and CD8. In contrast, we have been unable to document the presence of stem cells within the embryo itself at these early stages. These results support the hypothesis that the stem cells capable of populating the thymic rudiment originate in the yolk sac, and that their presence as early as at the 2- to 9-somite stage may indicate that prethymic stem cells found elsewhere in the embryo at later times may have been derived by migration from this extra-embryonic site. Our experimental design does not exclude the possibility of multiple origins of prethymic stem cells of which the yolk sac may provide the first wave of stem cells in addition to other later waves of cells.     

Developmental and Evolutionary Aspects of the Neurohypophysis

Although phylogenetic studies of neurohypophysial principlesare well advanced, studies of their development are rare. Fetalmammals have been shown to have unusually high vasopressor/oxytocicratios in their pituitaries. Paper chromatography of extractsfrom pituitaries of fetal sheep and fetal seals (Callorhinusursinus) indicated the presence of AVT, in addition to AVP andoxytocin. This was confirmed by the pharmacological and chemicalanalysis of AVT, purified from fetal seal pituitaries. The presenceof AVT suggested a "recapitulation" of a principle previouslyknown only in sub-mammalian vertebrates. Studies of ammocoetelarvae and adult lampreys (Lampetra nchardsoni) showed the presenceof AVT, but there was no evidence for any "recapitulation" ofan "early" neutral principle. It seemed possible that an apparentrecapitulation might occur only when the principle had a usein fetal life. Therefore the possible actions of AVT (and AVP)in the mammalian fetus (guinea pig) were studied. AVT and AVPwere shown to act on the isolated amnion to slow, and even reversefetal-maternal water movement. AVP acted on the yolk sac, thefetal skin and the fetal bladder to increase water flow inwards,towards the fetus. These actions suggested an extraplacentalmechanism for supplying water to the fetus and its environment,through the extraembryonic membranes. These actions were reminiscentof those known in the anurans. The apparent success of the conceptof recapitulation, in both the molecular and functional fields,may have been fortuitous. However, the results suggest thatphylogenetic considerations may well be useful in understandingthe physiology of the mammal during fetal life.