Alpha-fetoprotein,the major fetal serum protein,is not essential for embryonic development but is required for female fertility

The alpha-fetoprotein gene (Afp) is a member of a multigenic family that comprises the related genes encoding albumin, alpha-albumin, and vitamin D binding protein. The biological role of this major embryonic serum protein is unknown although numerous speculations have been made. We have used gene targeting to show that AFP is not required for embryonic development. AFP null embryos develop normally, and individually transplanted homozygous embryos can develop in an AFP-deficient microenvironment. Whereas mutant homozygous adult males are viable and fertile, AFP null females are infertile. Our analyses of these mice indicate that the defect is caused by a dysfunction of the hypothalamic/pituitary system, leading to anovulation.     

Tropomodulin1 is required in the heart but not the yolk sac for mouse embryonic development

Tropomodulin (Tmod)1 caps the pointed ends of actin filaments in sarcomeres of striated muscle myofibrils and in the erythrocyte membrane skeleton. Targeted deletion of mouse Tmod1 leads to defects in cardiac development, fragility of primitive erythroid cells, and an absence of yolk sac vasculogenesis, followed by embryonic lethality at embryonic day 9.5. The Tmod1-null embryonic hearts do not undergo looping morphogenesis and the cardiomyocytes fail to assemble striated myofibrils with regulated F-actin lengths. To test whether embryonic lethality of Tmod1 nulls results from defects in cardiac myofibrillogenesis and development or from erythroid cell fragility and subsequent defects in yolk sac vasculogenesis, we expressed Tmod1 specifically in the myocardium of the Tmod1-null mice under the control of the alpha-myosin heavy chain promoter Tg(alphaMHC-Tmod1). In contrast to Tmod1-null embryos, which fail to undergo cardiac looping and have defective yolk sac vasculogenesis, both cardiac and yolk sac morphology of Tmod1(-/-Tg(alphaMHC-Tmod1)) embryos are normal at embryonic day 9.5. Tmod1(-/-Tg(alphaMHC-Tmod1)) embryos develop into viable and fertile mice, indicating that expression of Tmod1 in the heart is sufficient to rescue the Tmod1-null embryonic defects. Thus, although loss of Tmod1 results in myriad defects and embryonic lethality, the Tmod1(-/-) primary defect is in the myocardium. Moreover, Tmod1 is not required in erythrocytes for viability, nor do the Tmod1(-/-) fragile primitive erythroid cells affect cardiac development, yolk sac vasculogenesis, or viability in the mouse.     

SCL/Tal-1 is essential for hematopoietic commitment of the hemangioblast but not for its development

In this report, we have defined the stage at which Scl functions in the establishment of the hematopoietic system and provide evidence that its primary role is in the generation of the hematopoietic lineages from a progenitor called the blast colony-forming cell (BL-CFC), a cell considered to be the in vitro equivalent of the hemangioblast. Using an embryonic stem (ES) cell line in which lacZ cDNA has been targeted to the Scl locus, we show that most of the BL-CFCs are detected in the SCL/lacZ- population, indicating that this progenitor does not express Scl. In the blast colony assay, Scl-/- cells initiate colony growth but are unable to generate endothelial and hematopoietic progeny and thus form colonies consisting of vascular smooth muscle cells only. The capacity to give rise to blast colonies can be rescued by retroviral transduction of a wild-type Scl gene into Scl-/- FLK-1+ cells, suggesting that the BL-CFC is generated in this population. Finally, we show that Scl-/- endothelial cells display a growth deficiency in monolayer cultures that can be partially overcome by maintaining this population as 3-dimensional aggregates indicating that specific cellular interactions are required for maintenance of the Scl-/- endothelial lineage in vitro.     

Histone deacetylase 1 (HDAC1), but not HDAC2, controls embryonic stem cell differentiation

Histone deacetylases (HDAC) 1 and 2 are highly similar enzymes that help regulate chromatin structure as the core catalytic components of corepressor complexes. Although tissue-specific deletion of HDAC1 and HDAC2 has demonstrated functional redundancy, germ-line deletion of HDAC1 in the mouse causes early embryonic lethality, whereas HDAC2 does not. To address the unique requirement for HDAC1 in early embryogenesis we have generated conditional knockout embryonic stem (ES) cells in which HDAC1 or HDAC2 genes can be inactivated. Deletion of HDAC1, but not HDAC2, causes a significant reduction in the HDAC activity of Sin3A, NuRD, and CoREST corepressor complexes. This reduced corepressor activity results in a specific 1.6-fold increase in histone H3 K56 acetylation (H3K56Ac), thus providing genetic evidence that H3K56Ac is a substrate of HDAC1. In culture, ES cell proliferation was unaffected by loss of either HDAC1 or HDAC2. Rather, we find that loss of HDAC1 affects ES cell differentiation. ES cells lacking either HDAC1 or HDAC2 were capable of forming embryoid bodies (EBs), which stimulates differentiation into the three primary germ layers. However, HDAC1-deficient EBs were significantly smaller, showed spontaneous rhythmic contraction, and increased expression of both cardiomyocyte and neuronal markers. In summary, our genetic study of HDAC1 and HDAC2 in ES cells, which mimic the embryonic epiblast, has identified a unique requirement for HDAC1 in the optimal activity of HDAC1/2 corepressor complexes and cell fate determination during differentiation.     

Glutathione synthesis is essential for mouse development but not for cell growth in culture

Glutathione (GSH) is a major source of reducing equivalents in mammalian cells. To examine the role of GSH synthesis in development and cell growth, we generated mice deficient in GSH by a targeted disruption of the heavy subunit of gamma-glutamylcysteine synthetase (gammaGCS-HS(tm1)), an essential enzyme in GSH synthesis. Embryos homozygous for gammaGCS-HS(tm1) fail to gastrulate, do not form mesoderm, develop distal apoptosis, and die before day 8.5. Lethality results from apoptotic cell death rather than reduced cell proliferation. We also isolated cell lines from homozygous mutant blastocysts in medium containing GSH. These cells also grow indefinitely in GSH-free medium supplemented with N-acetylcysteine and have undetectable levels of GSH; further, they show no changes in mitochondrial morphology as judged by electron microscopy. These data demonstrate that GSH is required for mammalian development but dispensable in cell culture and that the functions of GSH, not GSH itself, are essential for cell growth.     

Rous sarcoma virus is integrated but not expressed in chicken early embryonic cells.

We have developed a protocol that allows us to infect chicken early embryonic (CEE) cells with high efficiency. This was achieved by exposing the CEE cells to a semicontinuous dose of Rous sarcoma virus (RSV) for a period of 20 hr. Southern blot analysis indicated that an average of one proviral copy is integrated per embryonic cell. However, there was no production of infectious viral particles by the cells containing the proviral genome, although low levels of full-length genomic RNA could be detected by RNA transfer blot analysis. These low RNA levels contrast with the 100- to 1000-fold higher levels found in RSV-infected chicken embryo fibroblasts. We conclude that in cells derived from pregastrulating chicken embryos, RSV DNA is integrated into the cell genome but fails to be expressed in an efficient manner. These primary cells can therefore be used to identify factors involved in regulation of retroviral gene expression in normal cells. Such factors may also be instrumental in elucidating basic mechanisms involved in gene regulation during early development in higher vertebrates.     

Insulin expressing cells from differentiated embryonic stem cells are not beta cells

Aim/hypothesis Embryonic stem (ES) cells have been proposed as a potential source of tissue for transplantation for the treatment of Type 1 diabetes. However, studies showing differentiation of beta cells from ES cells are controversial. The aim of this study was to characterise the insulin-expressing cells differentiated in vitro from ES cells and to assess their suitability for the treatment of diabetes.Methods ES cell-derived insulin-expressing cells were characterised by means of immunocytochemistry, RT-PCR and functional analyses. Activation of the Insulin I promoter during ES-cell differentiation was assessed in ES-cell lines transfected with a reporter gene. ES cell-derived cultures were transplanted into STZ-treated SCID-beige mice and blood glucose concentrations of diabetic mice were monitored for 3 weeks.Results Insulin-stained cells differentiated from ES cells were devoid of typical beta-cell granules, rarely showed immunoreactivity for C-peptide and were mostly apoptotic. The main producers of proinsulin/insulin in these cultures were neurons and neuronal precursors and a reporter gene under the control of the insulin I promoter was activated in cells with a neuronal phenotype. Insulin was released into the incubation medium but the secretion was not glucose-dependent. When the cultures were transplanted in diabetic mice they formed teratomas and did not reverse the hyperglycaemic state.Conclusions/Interpretation Our studies show that insulin-positive cells in vitro-differentiated from ES cells are not beta cells and suggest that alternative protocols, based on enrichment of ES cell-derived cultures with cells of the endodermal lineage, should be developed to generate true beta cells for the treatment of diabetes.Abbreviations ES Embryonic stem - LIF leukemia inhibitory factor - ITSF insulin-transferrin-selenite-fibronectin.Bleackley and Korbutt laboratories contributed equally to this paper     

Insulin-like growth factor-I is essential for embryonic bone development

Although IGF-I has been identified as an important growth factor for the skeleton, the role of IGF-I on embryonic bone development remains unknown. Here we show that, in IGF-I-deficient (IGF-I(-/-)) mice, skeletal malformations, including short-limbed dwarfism, were evident at days post coitus (dpc) 14.5 to 18.5, accompanied by delays of mineralization in the spinal column, sternum, and fore paws. Reduced chondrocyte proliferation and increased chondrocyte apoptosis were identified in both the spinal ossification center and the growth plate of long bones. Abnormal chondrocyte differentiation and delayed initiation of mineralization was characterized by small size and fewer numbers of type X collagen expressing hypertrophic chondrocytes and lower osteocalcin expression. The Indian hedgehog-PTHrP feedback loop was altered; expression of Indian hedgehog was reduced in IGF-I(-/-) mice in long bones and in the spine, whereas expression of PTHrP was increased. Our results indicate that IGF-I plays an important role in skeletal development by promoting chondrocyte proliferation and maturation while inhibiting apoptosis to form bones of appropriate size and strength.     

Oxytocin is required for nursing but is not essential for parturition or reproductive behavior.

Oxytocin, a neurohypophyseal hormone, has been traditionally considered essential for mammalian reproduction. In addition to uterine contractions during labor and milk ejection during nursing, oxytocin has been implicated in anterior pituitary function, paracrine effects in the testis and ovary and the neural control of maternal and sexual behaviors. To determine the essential role(s) of oxytocin in mammalian reproductive function, mice deficient in oxytocin have been generated using embryonic stem cell technology. A deletion of exon 1 encoding the oxytocin peptide was generated in embryonic stem cells at a high frequency and was successfully transmitted in the germ line. Southern blot analysis of genomic DNA from homozygote offspring and in situ hybridization with an exonic probe 3' of the deletion failed to detect any oxytocin or neurophysin sequences, respectively, confirming that the mutation was a null mutation. Mice lacking oxytocin are both viable and fertile. Males do not have any reproductive behavioral or functional defects in the absence of oxytocin. Similarly, females lacking oxytocin have no obvious deficits in fertility or reproduction, including gestation and parturition. However, although oxytocin-deficient females demonstrate normal maternal behavior, all offspring die shortly after birth because of the dam's inability to nurse. Postpartum injections of oxytocin to the oxytocin deficient mothers restore milk ejection and rescue the offspring. Thus, despite the multiple reproductive activities that have been attributed to oxytocin, oxytocin plays an essential role only in milk ejection in the mouse.     

Mammalian ets-1 and ets-2 genes encode highly conserved proteins.

Cellular ets sequences homologous to v-ets of the avian leukemia virus E26 are highly conserved. In mammals the ets sequences are dispersed on two separate chromosomal loci, called ets-1 and ets-2. To determine the structure of these two genes and identify the open reading frames that code for the putative proteins, we have sequenced human ets-1 cDNAs and ets-2 cDNA clones obtained from both human and mouse. The human ETS1 gene is capable of encoding a protein of 441 amino acids. This protein is greater than 95% identical to the chicken c-ets-1 gene product. Thus, the human ETS1 gene is homologous to the chicken c-ets-1 gene, the protooncogene that the E26 virus transduced. Human and mouse ets-2 cDNA clones are closely related and contain open reading frames capable of encoding proteins of 469 and 468 residues, respectively. Direct comparison of these data with previously published findings indicates that ets is a family of genes whose members share distinct domains.     

Vitronectin is not essential for normal mammalian development and fertility.

Vitronectin (VN) is an abundant glycoprotein present in plasma and the extracellular matrix of most tissues. Though the precise function of VN in vivo is unknown, it has been implicated as a participant in diverse biological processes, including cell attachment and spreading, complement activation, and regulation of hemostasis. The major site of synthesis appears to be the liver, though VN is also found in the brain at an early stage of mouse organogenesis, suggesting that it may play an important role in mouse development. Genetic deficiency of VN has not been reported in humans or in other higher organisms. To examine the biologic function of VN within the context of the intact animal, we have established a murine model for VN deficiency through targeted disruption of the murine VN gene. Southern blot analysis of DNA obtained from homozygous null mice demonstrates deletion of all VN coding sequences, and immunological analysis confirms the complete absence of VN protein expression in plasma. However, heterozygous mice carrying one normal and one null VN allele and homozygous null mice completely deficient in VN demonstrate normal development, fertility, and survival. Sera obtained from VN-deficient mice are completely deficient in "serum spreading factor" and plasminogen activator inhibitor 1 binding activities. These observations demonstrate that VN is not essential for cell adhesion and migration during normal mouse development and suggest that its role in these processes may partially overlap with other adhesive matrix components.     

Renin-angiotensin system and hemangioblast development from human embryonic stem cells

Human embryonic stem cells (hESCs) offer the opportunity to create a novel source of blood cells for transfusion, transplantation and cancer immunotherapy. Identification of sequential progenitors leading to blood development, as well as a detailed understanding of the molecular mechanisms of hematopoietic lineage specification and diversification from hESCs, will be critical to advance technologies for large-scale production of blood cells and in vitro generation of hematopoietic stem cells. Multiple lines of evidence suggest that hematopoiesis, both in vivo during embryogenesis and in vitro from hESCs, is initiated from hemangioblasts; cells with the potential to generate both hematopoietic and endothelial cells. However, the phenotypic and functional properties of hemangioblasts remain largely unknown. The paper from Zambidis et al. is the first demonstration that hemangioblasts generated from hESCs express angiotensin-converting enzyme (CD143). More importantly, the current study demonstrates that the renin-angiotensin system plays a critical role in the hemangioblast fate decision to produce either blood or endothelial cells. These findings could be exploited for developing novel cellular and drug therapies for hematological and vascular diseases.