Novel zinc-responsive post-transcriptional mechanisms reciprocally regulate expression of the mouse Slc39a4 and Slc39a5 zinc transporters (Zip4 and Zip5).

Dietary zinc deficiency in mice is accompanied by enhanced expression of the zinc uptake transporter Slc39a4 (Zip4) and repressed expression of Slc39a5 (Zip5) in tissues which regulate zinc homeostasis (intestine, pancreas and visceral yolk sac). Herein, mechanisms controlling this differential expression were investigated. The induction of Zip4 mRNA during zinc deficiency, and its repression in response to zinc repletion were found to reflect changes in Zip4 mRNA stability and not changes in the relative rate of transcription of this gene. During zinc deficiency, ZIP4 protein levels are increased and this protein is localized on the apical membranes. Administration of an oral gavage of zinc caused ZIP4 internalization and degradation in enterocytes and visceral endoderm cells. Similarly, ZIP4 is induced by zinc deficiency in cultured mouse Hepa cells and is rapidly degraded in response to added zinc. Zip5 mRNA abundance does not change in response to zinc, but the translation of this mRNA was found to be zinc-responsive. During zinc deficiency, Zip5 mRNA remains associated with polysomes, while the protein is internalized and degraded in enterocytes, acinar cells and endoderm cells. After zinc-gavage, ZIP5 is rapidly resynthesized and targeted to the basolateral membranes of these cell types.

Haploinsufficiency of AML1 affects the temporal and spatial generation of hematopoietic stem cells in the mouse embryo.

The AML1:CBFbeta transcription factor complex is essential for definitive hematopoiesis. Null mutations in mouse AML1 result in midgestational lethality with a complete lack of fetal liver hematopoiesis. While the cell autonomous nature and expression pattern of AML1 suggest an intrinsic role for this transcription factor in the developing hematopoietic system, no direct link to a functional cell type has been made. Here, we examine the consequences of AML1 loss in hematopoietic stem cells (HSC) of the mouse embryo. We demonstrate an absolute requirement for AML1 in functional HSCs. Moreover, haploinsufficiency results in a dramatic change in the temporal and spatial distribution of HSCs, leading to their early appearance in the normal position in the aorta-gonad-mesonephros region and also in the yolk sac.

Vascularization in the murine allantois occurs by vasculogenesis without accompanying erythropoiesis.

The aim of this study was to determine whether the blood vessels of the murine allantois are formed by vasculogenesis or angiogenesis. Morphological analysis revealed that differentiation of allantoic mesoderm into an outer layer of mesothelium and an inner vascular network begins in the distal region of the allantois, which is most remote from other tissues, as early as the late neural plate stage (approximately 7.75 days postcoitum). Nascent blood vessels were not found in the base of the allantois until 4-somite pairs had formed in the fetus (approximately 8.25 days postcoitum), and vascular continuity with the yolk sac and fetus was not present until the 6-somite-pair stage (approximately 8.5 days postcoitum). Immunohistochemical analysis demonstrated that flk-1, a molecular marker of early endothelial cells, is expressed in significantly more distal than basal core cells in the early allantois and never in mesothelium. Furthermore, synchronous grafting of donor yolk sac containing blood islands into blood islands of headfold-stage host conceptuses provided no evidence that the yolk sac contributes endothelial cells to the allantois. Finally, when removed from conceptuses and cultured in isolation, neural plate and headfold-stage allantoises formed a conspicuous vascular network that was positive for Flk-1. Hence, the vasculature of the allantois is formed intrinsically by vasculogenesis rather than extrinsically via angiogenesis from the adjacent yolk sac or fetus. Whether allantoic vasculogenesis is associated with erythropoiesis was also investigated. Benzidine-staining in situ revealed that primitive erythroid cells were not identified in the allantois until 6-somite pairs when continuity between its vasculature and that of the yolk sac was first evident. Nevertheless, a small number of allantoises removed from conceptuses at a considerably earlier stage were found to contain erythroid precursor cells following culture in isolation. To determine whether such erythroid cells could be of allantoic origin, host allantoises were made chimeric with lacZ-expressing donor allantoises that were additionally labeled with [3H]methyl thymidine. Following culture and autoradiography, many lacZ-expressing benzidine-stained cells were observed in donor allantoises, but none contained silver grains above background. Moreover, no cells of donor allantoic origin were found in the fetus or yolk sac. Hence, vasculogenesis seems to be independent of erythropoiesis in the allantois and to involve a distal-to-proximal gradient in differentiation of allantoic mesoderm into the endothelial cell lineage. Furthermore, this gradient is established earlier than reported previously, being present at the neural plate stage.

Engraftment of embryonic hematopoietic cells in conditioned newborn recipients.

Yolk sac hematopoiesis is characterized by restricted hematopoietic cell differentiation. Although multipotent hematopoietic progenitor cells have been identified in the early yolk sac, long-term multilineage repopulating (LTMR) hematopoietic stem cell (HSC) activity has not been demonstrable before day 11 postcoitus (PC) using standard transplantation assays. In the present study, day-10 PC yolk sac hematopoietic cells were infused into myeloablated congenic newborn pups and donor cell engraftment and multilineage reconstitution of peripheral blood cells for at least 11 months in primary recipients was observed. In contrast, transplantation of day-10 PC yolk sac cells into congenic adult recipients did not result in engraftment despite pretransplant conditioning of the recipients or use of recipients that were genetically deficient in stem cells. Although fresh yolk sac cells were incapable of reconstitution when injected into adult recipient mice, yolk sac donor-derived cells residing in the bone marrow of primary newborn transplant recipients were capable of efficient reconstitution of conditioned secondary recipient adult mice. Primary newborn and secondary adult recipient animals engrafted with yolk sac cells were observed to have normal peripheral blood white blood cell counts. Lymphocyte subsets in peripheral blood, thymus, and spleen were also similar to control animals. The distribution and frequency of lineage-restricted progenitors derived from bone marrow of secondary transplant recipients were normal. These results indicate that day-10 PC yolk sac HSCs are capable of engrafting and reconstituting the hematopoietic system of conditioned newborn but not adult recipient animals. Furthermore, the ability of the yolk sac HSCs to differentiate into all hematopoietic lineages in these recipients strongly suggests that the local cellular microenvironment plays a prominent role in regulating yolk sac HSC differentiation.

Directed endothelial differentiation of cultured embryonic yolk sac cells in vivo provides a novel cell-based system for gene therapy.

Cultured murine yolk sac cells transfected with the cytomegalovirus immediate early promoter/human growth hormone (CMVIE-hGH) fusion gene, expressing high levels of hGH in culture, and suspended in Matrigel were subcutaneously (s.c.) injected into experimental mice. The injected cells were shown to form discrete vesicular structures within the Matrigel implant, suggesting directed differentiation of the embryonic yolk sac cells into endothelial tissue. Human growth hormone radioimmune assay of these mice showed sustained physiologically significant levels of hGH in their serum for beyond four months. These results confirmed that long-term cultured murine embryonic yolk sac cells can be induced to differentiate into endothelial cells both in vivo and in vitro and suggested a novel approach to the delivery to the circulation of therapeutic proteins for the treatment of inherited and acquired diseases.

Hemopoietic stem cells in murine embryonic yolk sac and peripheral blood.

Disaggregated embryonic yolk sac cells and circulating peripheral blood cells were obtained from normal murine day 9 embryos, prior to the formation of the fetal liver. These cells were microinjected transplacentally into days 11-15 W mutant anemic fetuses, when the fetal liver was the major hemopoietic organ. In a small proportion of the recipient animals examined after birth, long-term repopulation by the embryonic donor hemopoietic cells was observed. The donor hemopoietic stem cells proliferated and differentiated in the hosts as evidenced by the presence of donor hemoglobins in the growing recipient host animals. Some mothers of the pups were also repopulated by the donor stem cells. These results provide direct evidence that, during early murine embryogenesis, there are functional hemopoietic stem cells which are capable of colonizing the adult hemopoietic organs and probably the fetal liver and spleen to initiate hemopoiesis in these tissues.

Polyoma virus-induced hemangiomas in grafts of visceral yolk sac and of embryos.

The development of hemangiomas in grafts of visceral yolk sac and embryos after in vitro infection with polyoma virus is described. These hemangiomas were shown to be positive for the polyoma tumor-specific transplantation antigen(s) and to develop as well in recipient virgin as in pregnant rats. In grafts of fetal skin or gut infected with polyoma virus neoplastic transformation was never observed.

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.