Proliferating cell nuclear antigen (PCNA) as a proliferative marker during embryonic and adult zebrafish hematopoiesis

We investigated the expression of proliferative cell nuclear antigen (PCNA) in zebrafish to delineate the proliferative hematopoietic component during adult and embryonic hematopoiesis. Immunostaining for PCNA and enhanced green fluorescence protein (eGFP) was performed in wild-type and fli1-eGFP (endothelial marker) and gata1-eGFP (erythroid cell marker) transgenic fish. Expression of PCNA mRNA was examined in wild-type and chordin morphant embryos. In adult zebrafish kidney, the renal tubules are surrounded by endothelial cells and it is separated into hematopoietic and excretory compartments. PCNA was expressed in hematopoietic progenitor cells but not in mature neutrophils, eosinophils or erythroid cells. Some PCNA+ cells are scattered in the hematopoietic compartment of the kidney while others are closely associated with renal tubular cells. PCNA was also expressed in spermatogonial stem cells and intestine crypts, consistent with its role in cell proliferation and DNA synthesis. In embryos, PCNA is expressed in the brain, spinal cord and intermediate cell mass (ICM) at 24 h-post fertilization. In chordin morphants, PCNA is significantly upregulated in the expanded ICM. Therefore, PCNA can be used to mark cell proliferation in zebrafish hematopoietic tissues and to identify a population of progenitor cells whose significance would have to be further investigated.     

More than blood, a novel gene required for mammalian postimplantation development

More than blood (Mtb) is a novel gene that is widely expressed in mouse embryos prior to gastrulation but is subsequently restricted to specific tissues, including the developing central nervous system and hematopoietic organs. Since MTB is highly expressed in the fetal liver and developing thymus, we predicted that MTB would be required for hematopoiesis and that embryos deficient in MTB would die of anemia. Surprisingly, embryos with a targeted disruption of Mtb died prior to the initiation of blood cell development, immediately following implantation. This lethality is due to a defect in expansion of the inner cell mass (ICM), as Mtb(-/-) blastocysts failed to exhibit outgrowth of the ICM, both in vitro and in vivo. Furthermore, Mtb(-/-) blastocysts exhibited a higher frequency of apoptotic cells than wild-type or heterozygous blastocysts. These findings demonstrate that Mtb is a novel gene that is essential for early embryonic development.     

Role of the thrombopoietin (TPO)/Mpl system: c-Mpl-like molecule/TPO signaling enhances early hematopoiesis in Xenopus laevis

Multiple organs are induced in the primitive embryonic ectoderm excised from blastula stage Xenopus laevis embryos, under the strict control of mesoderm inducing factors. This in vitro system is useful for exploring the mechanisms of development. In this study, the function of thrombopoietin (TPO)/c-Mpl signaling in the development of hematopoietic cells was investigated. An optimal hematopoietic cell induction system was established to evaluate the influence of growth factors on hematopoiesis. It was found that exogenous TPO enhanced hematopoiesis in explants induced by activin and bone morphogenetic protein (BMP)-4 and increased the number of both erythrocytes and leukocytes in a dose-dependent manner. Addition of anti-c-Mpl antibody completely inhibited the expansion of hematopoietic cells stimulated by TPO, and the antibody specifically recognized blood-like cells. These results demonstrate that TPO acts on hematopoietic progenitors induced in explants and the c-Mpl-like molecule in Xenopus mediates the cellular function of TPO. We also found that forced expression of TPO in embryos promoted hematopoiesis in the ventral blood island and the dorsal-- lateral plate mesoderm. These results suggest that hematopoietic stem and progenitor cells are regulated by TPO/c-Mpl signaling from when they appear in their ontogeny. They also suggest that TPO/c-Mpl signaling play a crucial role in the formation of hematopoietic cells in Xenopus.     

Caudal genes in blood development and leukemia

Members of the caudal gene family (in mice and humans: Cdx1, Cdx2, and Cdx4) have been studied during early development as regulators of axial elongation and anteroposterior patterning. In the adult, Cdx1 and Cdx2, but not Cdx4, have been intensively explored for their function in intestinal tissue homeostasis and the pathogenesis of gastrointestinal cancers. Involvement in embryonic hematopoiesis was first demonstrated in zebrafish, where cdx genes render posterior lateral plate mesoderm competent to respond to genes specifying hematopoietic fate, and compound mutations in cdx genes thus result in a bloodless phenotype. Parallel studies performed in zebrafish embryos and murine embryonic stem cells (ESCs) delineate conserved pathways between fish and mammals, corroborating a BMP/Wnt-Cdx-Hox axis during blood development that can be employed to augment derivation of blood progenitors from pluripotent stem cells in vitro. The molecular regulation of Cdx genes appears complex, as more recent data suggest involvement of non-Hox-related mechanisms and the existence of auto- and cross-regulatory loops governed by morphogens. Here, we will review the role of Cdx genes during hematopoietic development by comparing effects in zebrafish and mice and discuss their participation in malignant blood diseases.     

Bone morphogenetic proteins in vertebrate hematopoietic development

During embryonic development, the hematopoietic system is the first to generate terminally differentiated, functional cell types. The urgent necessity for the early formation of blood and blood vessels during embryogenesis means that the induction, expansion, and maturation of these systems must be rapidly and precisely controlled. Bone morphogenic proteins (BMPs) have been implicated in hematopoietic development in the vertebrate embryo and stimulate the proliferation and/or differentiation of human cord blood hematopoietic stem cells (HSC) and embryonic stem cells in vitro. Here we review the mechanisms of action and potential roles of these soluble signaling molecules in vertebrate hematopoiesis.     

FLT4 基因在斑马鱼早期发育过程中的表达

目的:研究FLT4(VEGFR3)基因在斑马鱼早期发育过程中的表达。方法:提取斑马鱼胚胎的总RNA,制备地高辛标记的FLT4RNA反义探针,WISH(整胚胎原位杂交)研究FLT4在斑马鱼早期发育过程中的表达。结果:成功合成FLT4基因探针,获得FLT4基因在斑马鱼早期发育过程中的表达情况:FlT4在2-cell、32-cell、oblong、shield期前普遍性表达(0.75h、1.7h、3.7h、6h);24h在头部表达较多,特别是在ICM(intermediate cell mass,中间细胞群)区处有特异性表达;48h、72h在头部表达均较高表达。结论:FLT4在早期参与了血管的形成和造血的发生,在脑部和肾小管的发育中可能起到了重要作用。     

Gfi1.1 regulates hematopoietic lineage differentiation during zebrafish embryogenesis

Growth factor independence 1 （GFI1） is important for maturation of mammalian lymphocytes and neutrophils and maintenance of adult hematopoietic stem cells （HSCs）. The role of GFI1 in embryonic hematopoiesis is less well characterized. Through an enhancer trap screen and bioinformatics analysis, we identified a zebrafish homolog of Gill （named grill） and analyzed its function during embryonic development. Expression of both an endogenous griLl gene and a GFP reporter gene inserted near its genomic locus was detected in hematopoietic cells of zebrafish embryos. Morpholino （MO） knockdown of gill.1 reduced expression of scl, Imo2, c-myb, mpo, ragl, gatal and hemoglobin alpha embryonic-1 （hbael）, as well as the total amount of embryonic hemoglobin, but increased expression ofpu.1 and l-plastin. Under the same conditions, MO injection did not affect the markers involved in vascular and pronephric development. Conversely, overexpression of gill.1 via mRNA injection enhanced expression ofgatal but inhibited expression ofpu.1. These findings suggest that Gill.1 plays a critical role in regulating the balance of embryonic erythroid and myeloid lineage determination, and is also required for the differentiation of lymphocytes and granulocytes during zebrafish embryogenesis.     

Survival of porcine inner cell masses in culture and after injection into blastocysts

Isolation of embryonic stem cells has been documented only in the mouse and perhaps the hamster and cow. We report results of experiments designed to determine the effect of age of porcine embryos (6 through 10 d after the first day of estrus) on isolation of cell lines with embryonic stem cell-like morphology. The capacity of fresh and short-term cultured inner cell mass (ICM) cells to differentiate into normal tissues after injection into blastocysts was also measured. Few Day-6 ICM survived in culture to the first passage onto fresh feeder cells, but cell lines with embryonic stem cell-like morphology developed from Day-7 through Day-10 ICM. Isolation of embryonic stem cell-like colonies was achieved at a higher frequency from ICM isolated from older embryos, but embryonic stem cell-like colonies from older embryos also tended to differentiate spontaneously in culture. Viable porcine chimeras were born after injection of fresh ICM into blastocysts that were transferred to recipients for development to term; no chimeras were born from blastocysts injected with ICM subjected to short-term (1 to 6 d) culture. Germ-cell chimerism was confirmed in one of the chimeras. These results document that undifferentiated cells can be removed from porcine blastocysts, transplanted to other embryos, and contribute to development of normal differentiated tissues, including germ cells. Cells with embryonic stem-like morphology can be isolated in culture from ICM at various embryonic ages, but ICM from young blastocysts (e.g., Day-7 embryos) yield embryonic stem cell-like colonies at lower frequency than do ICM from older blastocysts (e.g., Day-10 embryos).     

Patterns of angiogenic and hematopoietic gene expression during brown trout embryogenesis

In this article, whole mount in situ hybridization is used to examine early blood vessel and blood cell development in the embryos of the brown trout Salmo trutta lacustris. cDNAs encoding for the angiogenic markers fli1 and flk1, and for the hematopoietic markers gata1 and gata2, were identified from an expressed sequence tag library of rainbow trout. Results show that fli1, flk1 and gata2 are activated in bilateral bands of the lateral trunk mesoderm before the onset of somitogenesis, shortly followed by gata1. These bands then converge toward the ventral midline to form the intermediate cell mass (ICM) (anterior ICM). Subsequent axial vasculogenesis and initial blood cell formation involve a clear spatial separation of fli1 and gata gene expression. Fli1 staining is most intense within the axial vessel (dorsal aorta, posterior cardinal vein) forming and lateral ICM cells, whereas binding of gata1 and gata2 probes becomes confined to the central portion of ICM cells beneath the dorsal aorta. This is followed by a first wave of angiogenesis, indicated by expression of fli1 and flk1. This gives rise to the intersegmental, dorsal longitudinal anastomotic and intestinal vessels. Further angiogenesis and hematopoiesis are activated in the "posterior ICM" of the tail. Here, the absence of gata1 indicates that hematopoiesis in this tissue generates myeloid rather than erythroid cells. The results supplement and validate previous, now historical morphological work in salmonids, thus aiding the elucidation of a comprehensive general scheme of angiogenic and hematopoietic development in the teleost embryo.     

Cloning and expression of zebrafish genes encoding the heme synthesis enzymes uroporphyrinogen III synthase (UROS) and protoporphyrinogen oxidase (PPO).

Heme is synthesized from glycine and succinyl CoA by eight heme synthesis enzymes. Although genetic defects in any of these enzymes are known to cause severe human blood diseases, their developmental expression in mammals is unknown. In this paper, we report two zebrafish heme synthesis enzymes, uroporphyrinogen III synthase (UROS) and protoporphyrinogen oxidase (PPO) that are well conserved in comparison to their human counterparts. Both UROS and PPO formed pairs of bilateral stripes in the lateral plate mesoderm at the 15-somite stage. At 24 h post-fertilization (hpf), UROS and PPO were predominantly expressed in the intermediate cell mass (ICM) that is the major site of primitive hematopoiesis. The expression of UROS and PPO was drastically suppressed in the bloodless mutants cloche and vlad tepes/gata 1 from 15-somite to 24hpf stages, indicating that both cloche and vlad tepes/gata 1 are required for the induction and maintenance of UROS and PPO expression in the ICM.     

Cell fate in the polar trophectoderm of mouse blastocysts as studied by microinjection of cell lineage tracers

Horseradish peroxidase (HRP), together with Fast Green or rhodamine-conjugated dextran (RDX), was used as an intracellular lineage tracer to determine cell fate in the polar trophectoderm of 3.5-day-old mouse embryos. In HRP-injected midstage (approximately 39-cell) and expanded (approximately 65-cell) blastocysts incubated for 24 hr, the central polar trophectoderm cell was displaced from the embryonic pole an average of 20 micron (5% of blastocyst circumference) and 29 micron (6% of blastocyst circumference), respectively. Expanded blastocysts injected with HRP + Fast Green and incubated for 24 hr or with HRP + RDX and incubated for 48 hr showed a displacement of 24 micron (4% of blastocyst circumference) and 88 micron (14% of blastocyst circumference), respectively. Up to 10 HRP-positive trophectoderm cells were observed among embryos incubated for 48 hr, indicating that in those cases, the labeled progenitor cells had divided at least three times. Our observations show that the central polar trophectoderm cell divides in the plane of the trophectoderm in expanded blastocysts and, along with its descendants, is displaced toward the mural trophectoderm. The systematic tandem displacement of labeled cells and their descendants toward the abembryonic pole suggests the presence of a proliferative area at the embryonic pole of the blastocyst. Large shifts in inner cell mass (ICM) position in relation to the trophectoderm do not occur during blastocyst expansion. Furthermore, random movements within the polar trophectoderm population do not account for the replacement of labeled cells by unlabeled polar trophectoderm cells. Rather, we propose the hypothesis that the ICM contributes these replacement cells to the polar trophectoderm during blastocyst expansion.     

Zebrafish dax1 is required for development of the interrenal organ, the adrenal cortex equivalent

Mutations in the human nuclear receptor, DAX1, cause X-linked adrenal hypoplasia congenita (AHC). We report the isolation and characterization of a DAX1 homolog, dax1, in zebrafish. The dax1 cDNA encodes a protein of 264 amino acids, including the conserved carboxy-terminal ligand binding-like motif; but the amino-terminal region lacks the unusual repeats of the DNA binding-like domain in mammals. Genomic sequence analysis indicates that the dax1 gene structure is conserved also. Whole-mount in situ hybridization revealed the onset of dax1 expression in the developing hypothalamus at approximately 26 h post fertilization (hpf). Later, at about 28 hpf, a novel expression domain for dax1 appeared in the trunk. This bilateral dax1-expressing structure was located immediately above the yolk sac, between the otic vesicle and the pronephros. Interestingly, weak and transient expression of dax1 was observed in the interrenal glands (adrenal cortical equivalents) at approximately 31 hpf. This gene was also expressed in the liver after 3 dpf in the zebrafish larvae. Disruption of dax1 function by morpholino oligonucleotides (MO) down-regulated expression of steroidogenic genes, cyp11a and star, and led to severe phenotypes similar to ff1b (SF1) MO-injected embryos. Injection of dax1 MO did not affect ff1b expression, whereas ff1b MO abolished dax1 expression in the interrenal organ. Based on these results, we propose that dax1 is the mammalian DAX1 ortholog, functions downstream of ff1b in the regulatory cascades, and is required for normal development and function of the zebrafish interrenal organ.